Secure storage devices, with physical input device, for secure configuration in a configuration-ready mode

ABSTRACT

A secure storage device includes a physical key input device, a secure memory and a controller. The controller arbitrates access by a host to securely configure the device based on the device&#39;s mode of operation. The controller determines whether the device is in a configuration-ready mode based on information within the device. Only when the device is in the configuration-ready mode, the device may be configured by the host. When a device is in a non-configuration-ready mode, the device is prevented from being configured by the host, but the device can be set to the configuration-ready mode, for example, by nullifying configuration data (e.g., PINs), by creating new encryption key(s), and by setting the mode to the configuration-ready mode. A null PIN is unusable to unlock the device after being locked. A new encryption key is unusable to decrypt data previously stored in the device, making such data unrecoverable.

CROSS-REFERENCE TO RELATED APPLICATION

This application is a continuation application of application Ser. No.15/640,292, filed on Jun. 30, 2017, which is a continuation ofapplication Ser. No. 15/286,465, filed on Oct. 5, 2016, now U.S. Pat.No. 9,720,700, the entirety of each of which is incorporated herein byreference.

TECHNICAL FIELD

The present description relates in general to computing devices andstorage devices, and more particularly to, for example, withoutlimitation, storage devices with a physical input device for secureconfiguration in a configuration-ready mode.

BACKGROUND

Secure memory storage devices that are free from software typicallyrequire that all settings, administrator personal identificationnumbers, and user personal identification numbers be entered through aphysical keypad of each of the secure memory storage devicesindividually. When there are only one or two secure memory storagedevices, the process of entering such settings and identificationinformation is typically not challenging. However, as the number ofsecure memory storage devices for deployment increases, configuration ofthe secure memory storage devices becomes exponentially time consumingand burdensome to an operator that is programming each individual devicethrough the physical keypad.

The description provided in the background section should not be assumedto be prior art merely because it is mentioned in or associated with thebackground section. The background section may include information thatdescribes one or more aspects of the subject technology.

BRIEF DESCRIPTION OF THE DRAWINGS

The accompanying drawings, which are included to provide furtherunderstanding and are incorporated in and constitute a part of thisspecification, illustrate disclosed embodiments and together with thedescription serve to explain the principles of the disclosedembodiments. In the drawings:

FIG. 1 illustrates an example of architecture for configuring securestorage devices.

FIG. 2 is a block diagram illustrating an example of a secure storagedevice and a host.

FIG. 3A illustrates an example of an overall process for configurationof secure storage devices using a host.

FIG. 3B illustrates an example of a process of a communication exchangebetween one or more secure storage devices and a host for configurationof secure storage devices.

FIG. 3C illustrates an example of a process for establishing a secureconnection between a secure storage device and a host.

FIG. 3D illustrates an example of a process for reconfiguration of asecure storage device.

FIG. 3E illustrates an example of a process for creating configurationprofile data using a host.

FIG. 3F illustrates an example of a process for querying storedconfiguration profile data using a host.

FIGS. 4A through 4E illustrate examples of graphical user interfaces ata host for configuring secure storage devices as well as generating,managing and querying configuration profile data.

FIG. 5 is a block diagram illustrating an example of a computer systemwith which a host can be implemented.

In one or more implementations, not all of the depicted components ineach figure may be required, and one or more implementations may includeadditional components not shown in a figure. Variations in thearrangement and type of the components may be made without departingfrom the scope of the subject disclosure. Additional components,different components, or fewer components may be utilized within thescope of the subject disclosure.

DETAILED DESCRIPTION

The detailed description set forth below is intended as a description ofvarious implementations and is not intended to represent the onlyimplementations in which the subject technology may be practiced. Asthose skilled in the art would realize, the described implementationsmay be modified in various different ways, all without departing fromthe scope of the present disclosure. Accordingly, the drawings anddescription are to be regarded as illustrative in nature and notrestrictive.

In one or more implementations, a secure storage device with heightenedsecurity does not require a software application (e.g., on a host) toencrypt the data stored in a memory, a hard drive, or a solid-statedrive of a secure storage device. Instead, a secure storage device usesa physical keypad that is used to unlock the secure storage device. Oncea secure storage device is unlocked, the device can present itself to ahost as a storage device.

A secure storage device that does not use a software application on ahost provides improved security but such secure device requires that allsettings, administrator personal identification numbers (PINs), and userPINs be entered through a physical keypad of the individual securestorage device. The process of entering such settings and PINs for oneor two secure storage devices can be manageable. However, as the numberof secure storage devices for deployment increases, configuration of thesecure storage devices becomes exponentially time consuming andburdensome to an operator that is programming each individual devicethrough the physical keypad. In some cases, the secure storage devicesmay be deployed with a default setting, allowing the end users to setthe PINs for the secure storage devices, where the end users become theadministrators of the devices. In some other cases, secure storagedevices may be set with PINs before deployment to the end users;however, knowledge of the PINs can become more widely known by more thanone operator prior to deployment to the end users.

The disclosed system addresses these challenges arising in the realm ofcomputer technology by providing a solution rooted in hardware, namely,by providing a special host software application that is enabled tolaunch a secure configuration of the secure storage device when thesecure storage device is determined to be in a configuration-ready mode.The configuration-ready mode represents a security feature to allow ordisallow the host software's access to the secure storage device. If thesecure storage device, which is plugged into the host, is in theconfiguration-ready mode, the secure storage device can be detected bythe host, and the host software can initiate a configuration process forconfiguring the secure storage device. On the other hand, when thesecure storage device is not in the configuration-ready mode, the hostsoftware does not initiate a configuration process and does notconfigure the secure storage device even when the secure storage deviceis physically plugged into the host. In one or more implementations,regardless of whether a secure storage device is in a locked state or ina unlocked state, when the secure storage device has been alreadyconfigured (and thus the device is in a non-configuration-ready mode),the host software does not configure the secure storage device while thedevice remains in the non-configuration-ready mode. In one or moreaspects, a secure storage device that has been already configured may bereset to change the mode of the secure storage device from anon-configuration-ready mode to the configuration-ready mode. In such asituation, while the secure storage device is in the configuration-readymode, the host software can configure such secure storage device. Thehost software may communicate with multiple secure storage devices on adata terminal for concurrent configuration of the devices when eachdevice is in the configuration-ready mode.

Various aspects of the subject technology relate to systems, methods,and machine-readable media for secure configuration of secure storagedevices in a configuration-ready mode. In one or more implementations, asecure storage device includes a secure memory and a securitycontroller. The security controller can arbitrate access by a host forconfiguring the secure storage device depending on a mode of operationof the secure storage device. The security controller determines whetherthe secure storage device is in a configuration-ready mode. Theconfiguration-ready mode indicates that the secure storage device isallowed to communicate with a host to configure the secure storagedevice. The security controller receives configuration data from thehost for configuring the secure storage device when the secure storagedevice is in the configuration-ready mode. In one or moreimplementations, the secure storage device is prevented from receivingthe configuration data from the host when the secure storage device isnot in the configuration-ready mode.

One or more implementations of the subject system provide severaladvantages, including providing enhanced security of the secure storagedevice during configuration, allowing configuration data from the hostto be deployed to an array of secure storage devices concurrently,preventing the secure storage device from any type of configuration byan external computing system when the secure storage device is not inthe configuration-ready mode, and limiting any exchange of data (e.g.,data that should be protected) between the secure storage device and thehost to occur only after a secure communication channel is establishedbetween the host and the secure storage device.

Furthermore, multiple hardware secure storage devices can be deployedeasily without compromising the security of the devices by not addingsoftware control to encryption engines in the devices. One or moreimplementations of the subject technology provide a secure method tostore the configuration data that has been set on the devices whendeployed. In addition, a user-friendly graphical user interface can beutilized to set the configuration settings and parameters within thesecure storage devices.

One or more implementations of the subject solution further provideimprovements to the functioning of the computer itself because itincreases the security performance of the data storage devices andminimizes security risks to data stored on the devices during theconfiguration process performed by a host external to the secure storagedevices. Specifically, in one or more implementations, the securestorage device requires to be in the configuration-ready mode ofoperation prior to any communication (e.g., communication that should beprotected) between the host and the secure storage device can takeplace, thereby reducing the likelihood of an unauthorized computingsystem obtaining unauthorized access to secure data potentially storedon the secure storage device by compromising control of the securestorage device through reconfiguration. In one or more implementations,reconfiguration of the secure storage device using the host software isnot possible when the secure storage device is not in theconfiguration-ready mode. In one or more implementations, each securestorage device in an array of secure storage devices may receive thesame or different configuration data from the host but uses anencryption key(s) (e.g., configuration encryption key(s)) unique to eachsecure storage device and unique for the configuration session, therebyincreasing the security performance with respect to the secure storagedevices.

The term “configuration-ready mode” may be, for example, indicating thata secure storage device is allowed to communicate with a host toconfigure the secure storage device (e.g., configure the secure storagedevice with configuration data such as security information and otherconfiguration setting(s)). The term “configuration-ready mode” may bereferred to as “config-ready mode,” “config-ready state,” or“configuration-ready state.”

In one or more implementations, when a secure storage device isunlocked, an access to the device is permitted. In one or moreimplementations, when a secure storage device is locked, an access tothe device is prevented. In one or more examples, when a locked securestorage devices (e.g., a locked device in a non-configuration-readymode) is plugged into a host, the locked device is not visible to thehost, and the locked device is not detectable by the host (e.g., notdetectable by the operating system at the host) as no information aboutthe locked device (e.g., no product identifier, vendor identifier, orother enumeration information about the device) is provided to the host.

FIG. 1 illustrates an example of architecture for configuration ofsecure storage devices suitable for practicing one or moreimplementations of the disclosure. The architecture 100 includes a host120 and secure storage devices 110 connected over a communication bus130.

The host 120 is operable to configure the secure storage devices 110with configuration data. In one or more implementations, configurationdata may include security information (e.g., one or more PINs). In oneor more implementations, configuration data may also include otherconfiguration setting(s). For purposes of deploying configuration dataconcurrently to an array of secure storage devices, multiple securestorage devices 110 can be connected to the host 120 over a common dataterminal (e.g., the communication bus 130).

The host 120 can be, for example, a desktop computer, a personalcomputer (PC), a server, a mobile computer, a tablet computer (e.g., ane-book reader), a mobile device (e.g., a smartphone or personal digitalassistant (PDA)), or any other type of devices or systems havingappropriate processor, memory, and communications capabilities forconfiguring the secure storage device(s) 110. The host 120 may includeone or more computing devices.

The secure storage device 110 can be a storage device having appropriateprocessor, memory, and communications capabilities for storing securedata, serving as a secure data back-up, and/or transferring secure data.The secure data may be accessible by various computing devices includingthe host 120 over the communication bus 130. A device 110 may besometimes referred to as a drive or a memory apparatus.

The communication bus 130 can include or can be a part of, for example,any one or more of a universal serial bus (USB), IEEE 1394, Ethernet,serial ATA, and/or any other type of communication bus, communicationinterface or communication port. A communication bus may be referred toas a communication channel, a communication medium, or vice versa.Further, the communication bus 130 can include, but is not limited to,any one or more of the following network topologies, including a busnetwork, a star network, a ring network, a mesh network, a star-busnetwork, tree or hierarchical network, or any other suitable type ofnetwork.

FIG. 2 is a block diagram illustrating an example of a secure storagedevice 110 and the host 120. The host 120 and the secure storage device110 are connected over the communication bus 130 via respectivecommunications modules 218 and 238.

The communications modules 218 and 238 are configured to interface withthe communication bus 130 to send and receive information, such as data,requests, responses, and commands between the host 120 and the securestorage device 110. The communications modules 218 and 238 can be, orcan be a part of, for example, serial bus connectors or interfaces. Thecommunications modules 218 and 238 may be referred to as, or mayinclude, network interfaces or communication interfaces. In one or moreexamples, the communications module 218 and the communication bus 130may be a part of a USB. In one example, the communications module 238may be a part of a USB connector, and the communications module 218 andthe communication bus 130 may be a part of a USB port(s), and the USBconnector may be connected to the USB port. In one example, each of thecommunications modules 218 and 238 and the communication bus 130 is awired communications module or bus. In another example, each of thecommunications modules 218 and 238 and the communication bus 130 may bea wireless communications module or bus. In one or more implementations,the communications modules 218 and 238 and the communication bus 130 mayinclude, or be part of, a wireless interface(s), a wireless port(s), awireless medium/media, and/or a wireless channel(s) to allow wirelesscommunications between a host and a secure storage device(s)).

The host 120 includes a processor 212 and a memory 220. The memory 220of the host 120 includes a configurator application 222 andconfiguration profile data 260. Configuration profile data may besometimes referred to as a configuration profile, configuration data, orvice versa. The memory 220 may be a read-and-write memory, a read-onlymemory, a volatile memory, a non-volatile memory, or a combination ofsome or all of the foregoing. From the memory 220, the processor 212 mayretrieve instructions to execute and data to process in order to executethe processes of the subject disclosure. The processor 212 can be asingle processor, multiple processors, or a multi-core processor indifferent implementations.

The secure storage device 110 includes a memory 232 and a securitycontroller 258. The secure storage device 110 may further include acommunications module 238, an input device 246, and an output device244. The input device may be referred to as a physical input device, aphysical key input device, or a key input device. The output device maybe referred to as a physical output device.

In one or more implementations, the secure storage device 110 includes acasing (e.g., 111 as illustrated in FIG. 1). The casing may be, forexample, a metal-based casing (e.g., aluminum) or a hardened plasticmaterial. The casing may be made of multiple parts. In one or moreimplementations, the memory 232 and the security controller 258 aredisposed within the casing.

The memory 232 is configured to store secure data (e.g., encrypteddata). The memory 232 may be, or may include, a read-and-write memory, aread-only memory, a volatile memory, a non-volatile memory, registers,or a combination of some or all of the foregoing. In some aspects, thememory 232 is a non-volatile memory unit that stores data even when thesecure storage device 110 is powered off. The memory 232 may include oneor more memories. The memory 232 may include a flash memory, a harddrive, a solid-state drive, or some combination thereof. In one or moreimplementations, the memory 232 is a mass storage device.

The memory 232 may be communicably coupled to the security controller258 via a bidirectional communication link 254. In one or moreimplementations, the link 254 is a high-speed serial advanced technologyattachment (SATA) for point-to-point connection between the memory 232and the security controller 258.

The physical input device 246 enables a user to communicate informationand select commands to the secure storage device 110. For example, thephysical input device 246 may receive a security identification code(e.g., one or more of an administrator PIN, a user PIN, a recovery PIN,a self-destruct PIN and/or a combination thereof) from a user tofacilitate unlocking of the secure storage device. The securityidentification code may also facilitate authentication of the user. Thephysical input device 246 may receive other control input to control theoperation of the secure storage device. For instance, the physical inputdevice 246 may receive a control input from a user to place the securestorage device 110, from a mode that is not configuration-ready, into aconfiguration-ready mode. In one example, when a user presses one ormore buttons on the physical input device 246, the security controller258 places the secure storage device into the configuration-ready mode.Such one or more buttons are predetermined and preset to cause thisoperation when pressed.

The physical input device 246 may include any acoustic, speech, visual,touch, tactile and/or sensory input device, such as a keypad, a pointingdevice, a dial, a sensor device (e.g., a biometric sensor, a fingersensor, biometric iris recognition sensor), or a touchscreen. In one ormore implementations, the physical input device 246 is disposed on or atan outer surface of the casing so that a user can access the physicalinput device. Having a physical input device on the secure storagedevice itself allows a user to securely access the device or preventaccess to the device without using an external system, such as a hostcomputer or host software. The physical input device 246 is configuredto receive an input provided by a user. In one or more implementations,the input includes one or more keypad entries, a biometric-based entry,a touch gesture entry, or a combination thereof.

The physical output device 244 may be disposed on or at the outersurface of the casing and configured to display an indication of theoperation of the secure storage device 110. Such indication may becontrolled by the security controller 258. The output device 244 mayenable, for example, the display or output of visual signaling by thesecurity controller 258. The indication may include a signal indicating(i) that a process has initiated to place the secure storage device intoa configuration-ready mode and/or (ii) that the secure storage device110 is in a configuration-ready mode. For example, this indication maybe displayed when a user presses one or more buttons on the physicalinput device 246 designated to set the secure storage device into aconfiguration-ready mode. In one aspect, an indication may be displayedon the output device 244, when the security controller 258 determinesthat the secure storage device 110 is in the configuration-ready mode.The output device 244 may also provide indications of other types ofoperation of the secure storage device, such as an indication that thedevice is locked or unlocked. The output device 244 may include anyvisual, auditory, tactile, and/or sensory output device to allow a userto detect an indication of the operation of the secure storage device110. One or more implementations may include a device(s) that functionsas both an input and output device, such as a touchscreen.

The communications module 238 of the secure storage device 110 isconfigured to connect the secure storage device 110 to the communicationbus 130 external to the casing. The communications module 238 mayinclude, or may be a part of, a single Standard-A USB plug to serve as aphysical interface to the communication bus 130 in some examples, or thecommunications module 238 may include, or may be a part of, a micro USBplug in other examples. In yet another example, the communicationsmodule 238 may include, or may be a part of, a Type-C connector. Theseare examples, and the communications module 238 is not limited to theseexamples. The communications module 238 may be, for example, disposedpartially within the casing and partially outside the secure storagedevice 110. In one or more examples, the communications module 238 iscoupled to and protrude from the casing.

In one or more implementations, the secure storage device 110 includes abattery(ies) (not shown) that may power the secure storage device 110 ora portion(s) thereof. In one example, the battery(ies) may power thesecurity controller 258 (or a portion(s) thereof), the physical inputdevice 246, and/or the physical output device 244. In anotherimplementation, the secure storage device 110 does not include abattery.

Still referring to FIG. 2, in one or more implementations, a securitycontroller 258 is coupled to the memory 232, the physical input device246, the physical output device 244, and the communications module 238.

In one example, a security controller 258 is a single controller. Inanother example, a security controller 258 includes multiple controllers(e.g., two controllers or more than two controllers). A controller maybe sometimes referred to as a microcontroller, a multi-core controller,a controller module, a processor, a processor module, a microprocessor,a microprocessor module, or a portion(s) thereof or vice versa. Acontroller(s) within a security controller 258 may be sometimes referredto as a microcontroller(s). A microcontroller may include one or moremicrocontrollers. When a security controller 258 has multiplemicrocontrollers, each microcontroller may perform different functions,and a microcontroller may be implemented with a different level ofsecurity protection (e.g., a high, medium, or low security level). Suchsecurity level may be implemented in hardware, firmware, or acombination thereof.

A security controller 258 may be a single integrated circuit (IC) chip(or a single die) or may include multiple IC chips. Multiple controllerswithin the security controller 258 may be on a single chip. Multiplecontrollers within the security controller 258 may be on separate chips.

In one or more implementations, a security controller 258 is not ageneral purpose processing device. In one or more implementations, asecurity controller 258 includes one or more application-specificdigital signal processors or one or more application-specific integratedcircuits. In one or more implementations, a security controller 258 mayinclude discrete hardware components or other suitable components thatcan perform the functions described herein. In one or more examples, asecurity controller 258 (or one or more microcontrollers therein) isimplemented in hardware and embedded firmware (without high-levelsoftware applications).

Microcontrollers within the security controller 258 may be coupled,directly or indirectly, to each other, using communication links. Acommunication link may be a serial peripheral interface (SPI) bus forsynchronous communication between the microcontrollers. A communicationlink may be a bidirectional communication link. A communication link maybe an inter-integrated circuit (VC) bus, where one microcontroller isimplemented as a master node and another microcontroller is implementedas a slave node, in some examples. These are examples, and acommunication link is not limited to these examples.

In one or more implementations, a security controller 258 includes alocal memory 240. The local memory 240 may be a read-and-write memory, aread-only memory, EEPROM, registers, a volatile memory, a non-volatilememory, or a combination of some or all of the foregoing. A local memory240 may be a single memory or multiple memories. A memory may includeone or more memories. When a security controller 258 includes multiplemicrocontrollers and multiple memories, each microcontroller may haveits associated local memory(ies). Such local memory(ies) may residewithin its corresponding microcontroller. Such local memory(ies) mayreside outside its corresponding microcontroller. A memory may beimplemented with a different level of security protection. The securitylevel may be implemented in hardware, firmware, or a combinationthereof.

The local memory 240 or a memory(ies) therein may be configured to storeinstructions and/or data, including parameters, flags, and/orinformation. The local memory 240 or a memory(ies) therein may storeinstructions/data that the security controller 258, a microcontroller(s)therein, and/or another component(s) may need at runtime. From the localmemory 240 (or a memory(ies) therein), the security controller 258, amicrocontroller(s) within the security controller 258, and/or anothercomponent(s) may retrieve instructions to execute and data to process inorder to execute the processes of the subject disclosure.

In one or more implementations, all instructions/data (e.g.,configuration data, other data, indications, keys, instructions,parameters, flags and information) stored in the secure storage device110 (e.g., 240) is encrypted or securely stored. In one or more otherimplementations, some instructions/data (e.g., a portion or some ofconfiguration data, other data, indications, keys, instructions,parameters, flags and/or information) stored in the secure storagedevice 110 (e.g., 240) is encrypted or securely stored. In one or moreyet other implementations, some instructions/data (e.g., configurationdata, other data, indications, keys, instructions, parameters, flagsand/or information) stored in the secure storage device 110 (e.g., 240)is not encrypted. In one or more implementations, the user data storedin the memory 232 is encrypted or securely stored.

The security controller 258 may provide instructions to prevent or allowdata transfer between the secure storage device 110 and an externalsystem (e.g., the host 120). The security controller 258 may prevent thehost 120 from accessing and configuring the secure storage device 110when the secure storage device 110 is not in a configuration-ready mode.

In one or more implementations, configuration data of a secure storagedevice is settable or changeable by a user. For example, a user (or anadministrator or an operator) may change configuration data such assecurity information (e.g., one or more PINs) or other configurationsettings (e.g., auto-lock, lock-override, or other settings) associatedwith a configuration of the secure storage device. This change can bemade by the secure storage device, for example, using a physical inputdevice (e.g., 246) of the secure storage device. In one or more aspects,this change by the secure storage device may be made when the securestorage device is in a configuration-ready mode or when the securestorage device is in a non-configuration ready mode. Furthermore,configuration data may be changed by a configurator application 222 whena secure storage device is in a configuration-ready mode. Securityinformation may be sometimes referred to as a security identificationcode, a security personal identification code, a personal identificationcode, a security parameter(s), or vice versa.

Illustration of Examples of Configuration-Ready Mode

In one or more implementations, a secure storage device 110 can be in aconfiguration-ready mode, for example, by being in (i) an “out-of-box”mode or (ii) a “user-set” configuration-ready mode. Theseimplementations provide security as well as secure flexibility.

In one or more other implementations, a configuration-ready mode isestablished only by being in an out-of-box mode, and suchimplementations do not allow a user-set configuration-ready mode. In oneor more aspects, these implementations provide heightened security as asecure storage device can be configured by an external system (e.g., ahost) only once, but these implementations do not provide theflexibility to reset a storage device back into a configuration-readymode by a user.

The descriptions below illustrate examples of an out-of-box mode.

In one or more implementations of an out-of-box mode, when a securestorage device 110 is in a factory sealed box or is out of the sealedbox without any input entered into the secure storage device by a user(e.g., a secure storage device is in a box shipped to a user or ready tobe shipped; or a box containing a secure storage device is opened, andthe device is out of the box but no input has been entered into thesecure storage device by a user), the secure storage device may beconsidered to be in an out-of-box mode. An “out-of-box mode” may bereferred to as an “out-of-box state” or a “brand new” state.

In some aspects of this out-of-box mode, no security information (e.g.,PINs) or other configuration settings (e.g., auto-lock, lock-override,etc.) have been applied and stored on the secure storage device 110. Inone or more implementations, the secure storage device thus does notcontain any configuration data, such as security information or otherconfiguration settings. The secure storage device is in a “pristine”state.

In one or more implementations, a secure storage device in an out-of-boxmode may be viewed as having “null” configuration data. Nullconfiguration data may include “null” security information (e.g., one ormore “null” PINs). In one or more implementations, null configurationdata may further include default configuration setting(s) (e.g., defaultsetting for auto-lock, default setting for lock-override, etc.).

In one or more examples, when a secure storage device 110 has “null”configuration data, all configuration data is null. For example, allsecurity information (e.g., all PIN(s)) is null. Further, for example,all other configuration settings (e.g., settings for auto-lock, bruteforce attempt, self-destruct, lock-override, key press led indicator,drive format, etc.) are set to their predetermined values (e.g., defaultvalues).

In one or more implementations, null configuration data is not enteredby a user. For example, null PIN(s) are not entered by a user. Further,for example, default configuration settings are not entered by a user.

Valid configuration data that is stored in a secure storage device 110is usable to operate the secure storage device, for example, during anormal operation (e.g., in a non-configuration-ready mode). Forinstance, a valid PIN (e.g., a valid administrator PIN, a valid userPIN) can be entered to unlock a device after the device is locked. Whena user enters a PIN, if the entered PIN matches the PIN stored in thesecure storage device 110, then the PIN is valid, which allows thedevice to unlock.

On the other hand, “null” configuration data (e.g., null PIN(s)) in thesecure storage device 110 is not usable to operate the secure storagedevice, for example, during a normal operation (e.g., in anon-configuration-ready mode). A null configuration data is not usablefor its intended purpose or function. For instance, a “null” PIN (e.g.,a null administrator PIN, a null user PIN, or a null self-destruct PIN)is not usable to unlock a device after the device is locked. A “null”recovery PIN is not usable to create a new valid PIN. When a securestorage device 110 contains a valid recovery PIN, this can place thedevice into a state of “user-forced enrollment” so that when a userenters the recovery PIN, the device 110 allows the user to enter a newPIN (e.g., a new administrator PIN or a new user PIN) that can be usedto unlock the device after being locked. However, a “null” recovery PINin the secure storage device 110 does not place the device into a stateof “user-forced enrollment” and thus does not allow a user to enter anew PIN to unlock the device after being locked.

In one or more implementations, while default configuration settings(e.g., default settings for auto-lock, lock-override, etc.) may beusable to operate the secure storage device during a normal operation(e.g., reading and writing to/from the memory 232), null PINs are notusable for the normal operation.

In one or more aspects, a null PIN is not a valid PIN. A null PIN may bea PIN in which at least a part or all parts of the PIN (e.g., anadministrator PIN, a user PIN, a recovery PIN, or a self-destruct PIN)is not enterable via the physical input device. For example, if thephysical input device 246 is a keypad having only alphanumeric keys, anull PIN may contain one or more characters, symbols or other items thatare not alphanumeric; hence, such null PIN cannot be entered via thekeypad. In one or more implementations, a null PIN is not all zeros. Inone or more implementations, all PINs are null PINs, and none of thenull PINs is all zeros.

In one or more implementations, a null PIN (e.g., a null administratorPIN, a null user PIN, or a null self-destruct PIN) is not usable tounlock the secure storage device 110 after the device is locked. In oneor more implementations, a null PIN (e.g., a null recovery PIN) is notusable to create a PIN to unlock the secure storage device 110 after thedevice is locked. In one or more implementations, a null PIN (e.g., anull administrator PIN, a null user PIN, a null self-destruct PIN, or anull recovery PIN) is not usable to facilitate unlocking the securestorage device after the device is locked.

In one or more aspects of an out-of-box mode, a secure storage device110 contains a brand new encryption key(s) (e.g., a new (or fresh) datatransfer encryption key for encrypting/decrypting data to/from a memory232). In one or more implementations, the new encryption key(s) may alsoinclude a new (or fresh) handshake key(s) to be used during a handshakeprocess. In one example, the handshake key(s) includes a handshakekey(s) for a secure storage device 110 (e.g., the security controller258 (or a microcontroller therein)). In another example, the handshakekey(s) includes a handshake key(s) for a host (e.g., the configuratorapplication 222). In one or more implementations, the securitycontroller 258 (or a microcontroller therein) generates the newencryption key(s). In one or more aspects, the secure storage device 110(e.g., the memory 232) is considered securely “erased” (e.g.,crypto-erased), and any encrypted data, if any, previously stored on thesecure storage device 110 (e.g., 232) is unrecoverable because anypreviously stored data (e.g., encrypted data that was stored in thesecure storage device before the new encryption key is generated) cannotbe decrypted using the new data transfer encryption key. The new datatransfer encryption key may be, however, used to encrypt new data to bestored into the secure storage device 110 (e.g., the memory 232) fromthe time the new data transfer encryption key is created.

In one or more aspects, having “new” encryption key(s) in this contextcan be understood as “erasing” or “removing” any encryption key(s) thatmight have been previously stored in a secure storage device 110 (e.g.,stored prior to creating the new encryption key(s)) and replacing themwith fresh or new encryption key(s). In one or more implementations, anew encryption key is different from a previous encryption key, if any.In one or more examples, an aspect of this can be understood as there isno data transfer encryption key in the secure storage device to decryptthe data previously stored in the secure storage device, or can beunderstood as there is a new data transfer encryption key in the securestorage device that is not usable to recover encrypted data previouslystored in the secure storage device (e.g., the memory 232).

In one or more aspects, a new data transfer encryption key is not usableto decrypt data, if any, previously stored in the memory 232; hence,encrypted data that was previously stored cannot be read from the memory232 using the new data transfer encryption key, and any encrypted datapreviously stored on the secure storage device 110 (e.g., 232) isunrecoverable.

For an out-of-box mode, an indication (e.g., a flag) is set within asecure storage device 110 indicating that the secure storage device 110is in a configuration-ready mode. For example, the security controller258 (or a microcontroller therein) may set this indication.

The descriptions below illustrate examples of a user-setconfiguration-ready mode.

A secure storage device 110 that is not in a configuration-ready modecan be set to a “user-set” configuration-ready mode by a user (e.g., anadministrator, an operator, any other person, or an entity who isassociated with or has a right to control the secure storage device).

For example, after a secure storage device 110 has been set with aPIN(s), and has stored encrypted user data in a memory (e.g., 232), if auser desires to place the secure storage device back into aconfiguration-ready mode, then the user can provide an input via thephysical input device 246 (e.g., pressing a predetermined key or keycombination) that is associated with placing the device into aconfiguration-ready mode. In response to the user input, the securestorage device 110, using, e.g., the security controller 258 (or amicrocontroller therein), may (i) “nullify” configuration data, (ii)create new encryption key(s), and (iii) reset a predesignated indicationto a configuration-ready mode (e.g., a flag in a register).

To reset a secure storage device into a user-set configuration-readymode, the security controller 258 (or a microcontroller therein) may“nullify” configuration data. In one or more implementations, nullifyingconfiguration data may include nullifying security information (e.g.,one or more PINs, such as administrator, user, recovery, andself-destruct PINs). In one or more implementations, nullifyingconfiguration data may further include resetting other configurationsetting(s) (e.g., settings for auto-lock, lock-override, self-destruct,etc.) previously stored in the secure storage device 110 into theirdefault settings. In one or more aspects, this nullifying process mayerase (or remove) and replace configuration data previously stored with“null” configuration data, such as “null” security information (e.g.,“null” PIN(s)). This nullifying process may erase and replace anypreviously stored configuration setting(s) with default configurationsetting(s). “Null” configuration data and “null” PINs in a user-setconfiguration-ready mode have the same or substantially similarfunctions and characteristics as the “null” configuration data and the“null” PINs described with respect to an out-of-box mode.

In one or more implementations of resetting a secure storage device intoa user-set configuration-ready mode, the security controller 258 (or amicrocontroller therein) creates new encryption key(s) (e.g., a new (orfresh) data transfer encryption key for encrypting/decrypting datato/from a memory 232). In one or more implementations, the newencryption key(s) may also include new (or fresh) handshake key(s) to beused during a handshake process. In one example, the handshake key(s)includes a handshake key(s) for a secure storage device 110. In anotherexample, the handshake key(s) includes a handshake key(s) for a host(e.g., the configurator application 222). In one or moreimplementations, creating new encryption key(s) may be understood as,for example, erasing (or removing or crypto-erasing) any encryptionkey(s) previously stored in the secure storage device 110 and replacingany such key(s) with new encryption key(s). “New” encryption key(s) in auser-set configuration-ready mode have the same or substantially similarfunctions and characteristics as the “new” encryption key(s) describedwith respect to an out-of-box mode.

When a secure storage device 110 is reset to a user-setconfiguration-ready mode, an indication (e.g., a flag) is set within asecure storage device 110 indicating that the secure storage device 110is in a configuration-ready mode. For example, the security controller258 (or a microcontroller therein) may set this indication.

In one or more implementations, when a secure storage device 110 is in aconfiguration-ready mode (e.g., an out-of-box mode or a user-setconfiguration-ready mode), all configuration data is null. In one ormore implementations of a configuration-ready mode, the secure storagedevice 110 does not contain any security information (or any securityidentification code, such as any PIN) that is enterable (e.g., via thephysical input device 246) to facilitate unlocking the secure storagedevice after the device is locked. Described in another way, in one ormore implementations of a configuration-ready mode, the secure storagedevice 110 does not contain any security information (or any securityidentification code, such as any PIN) that is enterable (e.g., via thephysical input device 246) to unlock the secure storage device after thedevice is locked. Explained in another way, in one or moreimplementations of a configuration-ready mode, none of the securityinformation (e.g., none of the PIN(s)) contained in the secure storagedevice is usable or enterable (e.g., via the physical input device 246)to unlock the secure storage device after the device is locked.

In one or more implementations, to place a secure storage device into aconfiguration-ready mode (e.g., an out-of-box mode or a user-setconfiguration-ready mode), the following steps may be performedconcurrently or sequentially: nullifying the configuration data,creating new encryption key(s), and resetting the configuration-readymode indication. For example, nullifying configuration data and creatingnew encryption key(s) may be performed concurrently or sequentially andthen after the successful completion of the foregoing steps (i.e.,nullifying and creating steps) is verified, the configuration-ready modeindication may be reset.

In one aspect of one or more implementations, the security controller258 (or a microcontroller therein) determines whether the secure storagedevice 110 is in a configuration-ready mode by reading an indication(e.g., a flag in the device 110) of a mode of operation and determiningwhether the indication is set to indicate that the secure storage device110 is in the configuration-ready mode. When a configuration-ready modeflag in the device 110 is set (e.g., a predetermined value indicating aconfiguration-ready mode), the secure storage device 110 is determinedto be in a configuration-ready mode. In one aspect of one or moreimplementations, the device 110 makes the determination without usingany information (e.g., any instructions or data) from outside the device110. In one aspect of one or more implementations, the determination isindependent of any information from a host (e.g., independent of anyinput, inquiry, instructions or data from the configurator application222). In one aspect of one or more implementations, the determination isindependent of the device type. In one aspect of one or moreimplementations, the determination is made using a self-determinationprocess performed entirely by the device 110.

In another aspect of one or more implementations, the securitycontroller 258 (or a microcontroller therein) may determine whether thesecure storage device 110 is in a configuration-ready mode by examiningwhether security information (e.g., a PIN(s)) contained in the securestorage device 110 is null. In this respect, the security controller 258may perform a read operation of a memory within the device 110 wheresuch security information is stored and determine the status of suchsecurity information. The security controller 258 determines that thesecure storage device 110 is in the configuration-ready mode when thesecure storage device 110 is determined to include null securityinformation (e.g., all PINs are null). The security controller 258 (or amicrocontroller therein) may determine that the secure storage device110 is not in the configuration-ready mode when the secure storagedevice 110 is determined to include valid security information (e.g., atleast one PIN is not null). Hence, when the secure storage device 110contains valid security information, the secure storage device 110 isnot in a configuration-ready mode.

In one or more examples, when a secure storage device 110 is in aconfiguration-ready mode, the output device 244 may indicate thisconfiguration-ready mode by emitting one or more lights such as greenand blue light-emitting diodes (LEDs).

Once the security controller 258 of a secure storage device 110determines that the device 110 is in a configuration-ready mode, and ifthe device 110 is plugged into a host 120, the security controller 258(or a microcontroller therein) may provide the indication of theconfiguration-ready mode (via the communications module 238) to thecommunication bus 130 for provision to the host so that the host 120 candetermine that the device 110 is in a configuration-ready mode based onthe indication received from the device 110.

As an illustration, when a secure storage device 110 is in aconfiguration-ready mode, the security controller 258 (or amicrocontroller therein) provides instructions to open the securestorage device upon power up with a special flag. The configuratorapplication 222 of the host 120 seeks for the flag (e.g., via an USBcall) upon detection of a connected secure storage device, and if theflag is set, the configurator application 222 determines that the securestorage device is in a configuration-ready mode and ready forconfiguration.

Explaining the above illustration in a different way, when a securestorage device 110 is plugged into a host 120, and whenever the securestorage device is in a configuration-ready mode, the security controller258 provides instructions to open on a configuration-ready state withthe configuration-ready flag set. When the configurator application 222communicates with the secure storage device 110 via the securitycontroller 258, the configurator application 222 can read the value ofthe configuration-ready flag and determine that the secure storagedevice is in a configuration-ready mode.

In one or more implementations, the host 120 (e.g., the configuratorapplication 222) can configure a secure storage device 110 only when thesecure storage device 110 is in a configuration-ready mode. In otherwords, the host 120 cannot configure a secure storage device that is ina non-configuration-ready mode.

Illustration of Examples of Operations of Device and Host

In one or more implementations, the security controller 258 (or amicrocontroller(s) therein) of the secure storage device 110 isconfigured to execute instructions, such as instructions physicallycoded into the security controller 258 (or the microcontroller(s)),instructions received from firmware in the local memory 240 (or thememory(ies) associated with the respective microcontroller(s)), or acombination of both. For example, the security controller 258 (or amicrocontroller therein) executes instructions to cause detecting thatthe secure storage device 110 is powered on, when the secure storagedevice 110 is applied with power, e.g., from the host 120 via thecommunication bus 130 when the secure storage device 110 is plugged intoa port associated with the communication bus 130. In one or moreexamples, the communications module 238 of the secure storage device 110includes, or is a part of, a powered USB interface.

In one implementation, the security controller 258 (or a microcontrollertherein) determines whether the secure storage device 110 is in aconfiguration-ready mode after detecting the device 110 (or the securitycontroller 258, or a portion(s) thereof) is powered on or after thedevice 110 (or the security controller 258, or a portion(s) thereof) ispowered on. In another implementation, the security controller 258 (or amicrocontroller therein) may determine whether the secure storage device110 is in a configuration-ready mode before detecting the device 110 (orthe security controller 258, or a portion(s) thereof) is powered on orbefore the device 110 (or the security controller 258, or a portion(s)thereof) is powered on. In one or more examples, the device 110 (e.g.,the entire device 110, the security controller 258, or a portion(s) ofthe device 110) may be powered on by the host via the communicationsmodule 238.

The security controller 258 (or a microcontroller therein) is configuredto cause sending an instruction or data to the host 120 via thecommunication module 238 when the secure storage device 110 isdetermined to be in the configuration-ready mode. For example, amicrocontroller within the security controller 258 may send theinstruction or data to a second microcontroller via a communicationlink, and the second microcontroller may send the instruction or data tothe host 120 via the communication module 238. In some examples, thedata may include identifier information associated with the securestorage device 110 and/or other enumeration information. Thecommunication bus 130 may be associated with a USB communicationprotocol such that the identifier information and/or other enumerationinformation are placed on the communication bus 130 in accordance withthe USB communication protocol. In one or more implementations, theidentifier information includes a product identifier (e.g., USB productID) and a vendor identifier (e.g., USB vendor ID).

In one or more implementations, the identifier information (e.g., theproduct identifier and vendor identifier) is a part of enumerationinformation. Enumeration may be a process of detecting and identifying adevice attached to a host, such as a secure storage device. In one ormore implementations, enumeration information may include a devicedescriptor, a configuration description, and an interface descriptor. Inone example, enumeration information includes USB enumerationinformation, which may include, for example, a USB product ID, USBvendor ID, USB device type, USB device class, USB device speed, USBdevice descriptor, etc. In one or more implementations, enumerationinformation is not settable or changeable by a user. In one or moreimplementations, enumeration information is permanent informationdescribing a device.

In one or more implementations, the processor 212 on the host, using forexample an operating system of the host, may scan the communication bus130 and identify the secure storage device 110 as one of the devicesconnected to the host 120 based on the identifier information and/orother enumeration information provided by the secure storage device orscanned by the host (e.g., by the operating system of the host). Theprocessor 212, e.g., the configurator application 222 running thereon,may then send a query, to the secure storage device 110 (or to each ofthe secure storage devices 110) connected to the host 120, requestinginformation as to whether the secure storage device is in aconfiguration-ready mode. In response to the query, the securitycontroller 258 of the secure storage device 110 may provide theindication of the configuration-ready mode (e.g., the value of theconfiguration-ready mode flag) to the host 120 via the communicationsmodule 238 and the communication bus 130. For example, a microcontrollerwithin the security controller 258 may provide the indication to asecond microcontroller, which provides the indication to the host viathe communications module 238 and the communication bus 130.

In another implementation, the security controller 258 (or amicrocontroller therein) may provide the indication, for transmission tothe host, without the host 120 (e.g., the configurator application 222)requesting such information. In one example, the indication may beprovided upon completion of an enumeration process.

In one or more implementations, the enumeration process (e.g.,providing/obtaining the identifier information and other enumerationinformation) is performed by the secure storage device 110 and the host(e.g., the operating system of the host) without encryption. In one ormore implementations, the indication of the configuration-ready mode isprovided from the secure storage device 110 (e.g., a microcontrollertherein) to the host 120 (e.g., the processor 212 running theconfigurator application 222) without encryption. In anotherimplementation, the indication may be provided using a secure method.

The processor 212 (e.g., the configurator application 222) and thesecurity controller 258 (or a microcontroller therein) are configured tocause facilitating a handshake process when the secure storage device110 is determined to be in the configuration-ready mode. In one or moreimplementations, the host 120 (e.g., the configurator application 222using the processor 212) and the device 110 (e.g., the securitycontroller 258 or a microcontroller therein) perform a handshake andestablish a new secure encryption key(s), which may be referred to as aconfiguration encryption key(s).

In one or more implementations, the configuration encryption key(s) maybe generated based on the handshake process (e.g., based on the dataprovided during the handshake process). In one or more implementations,the host 120 and the secure storage device 110 create a configurationencryption key(s) based on one or more handshake key(s). In one example,the processor 212 (e.g., the configurator application 222) generates aconfiguration encryption key for the host based on one or more handshakekey(s). In one example, the security controller 258 (or amicrocontroller therein) generates a configuration encryption key forthe device 110 based on one or more handshake key(s).

The configuration encryption key(s) may be used to encrypt theconfiguration data (e.g., by the configurator application 222 using theprocessor 212) and to decrypt the configuration data (e.g., by thesecurity controller 258 or a microcontroller therein).

In another implementation, a configuration encryption key may beestablished without using a handshake process. In one example, aconfiguration encryption key may be a predetermined key, and is notgenerated at runtime of the configurator application. In one example, nohandshake keys are used or generated during a configuration process. Inanother implementation, the host and secure storage device may utilizeother methods of a handshake process. In another implementation, thehost and the secure storage device may utilize other methods to create aconfiguration encryption key(s).

The security controller 258 (or a microcontroller therein) executesinstructions to cause receiving configuration data from the host 120 viathe communication bus 130 for configuring the secure storage device 110when the secure storage device 110 is determined to be in theconfiguration-ready mode. In some examples, the secure storage device110 is prevented from receiving the configuration data from the host 120when the secure storage device 110 is determined not to be in theconfiguration-ready mode. In one or more implementations, the host 120,e.g., the configurator application 222, retrieves the configurationprofile data 260 and encodes the configuration data using aconfiguration encryption key (e.g., the host's configuration encryptionkey). In this respect, encrypted configuration data is passed to thesecure storage device 110 from the host 120 over a secure communicationchannel via the communication bus 130. In the illustration, the securitycontroller 258 (or a microcontroller therein) receives the configurationdata, and the security controller 258 (or the microcontroller therein)decrypts the encrypted configuration data received from the host 120using a configuration encryption key (e.g., the device's configurationencryption key).

In one or more implementations, the security controller 258 (or amicrocontroller therein) is configured to cause initiating, based on thedetermination that the secure storage device 110 is in theconfiguration-ready mode, configuration of the secure storage device 110using the received configuration data. Once decrypted by the securitycontroller 258 (or a microcontroller therein), the security controller258 (or a microcontroller therein) may begin to load securityinformation (e.g., one or more PINs) and other configuration setting(s)(e.g., auto-lock, self-destruct, lock-override settings) for storageinto the secure storage device 110. The configuration data, once loadedinto the secure storage device 110, enables the secure storage device110 to store and/or transfer secure data (e.g., into/from the memory232) for a user(s) of the secure storage device 110 based on the loadedconfiguration profile. In one or more implementations, the configurationdata contains at least one PIN that is usable or enterable (via thephysical input device 246) to facilitate unlocking (or to unlock) thesecure storage device 110 after being locked. The security controller258 (or a microcontroller therein) then determines whether theconfiguration of the secure storage device 110 is complete.

In one or more implementations, the security controller 258 (or amicrocontroller therein) stores an indication that the secure storagedevice 110 is not in the configuration-ready mode when the configurationof the secure storage device 110 is determined to be complete. Forexample, the security controller 258 (or a microcontroller therein) maymodify the value of the configuration-ready flag in the secure storagedevice 110 from a value (e.g., 1) that represents a configuration-readystate to another value (e.g., 0) that represents anon-configuration-ready state.

The security controller 258 (or a microcontroller therein) then maycause termination of the configuration session with the host (e.g.,terminating the communication with the host 120 or terminating aconnection to the host 120) via the communication bus 130 when theconfiguration of the secure storage device 110 is determined to becomplete. The change in the flag setting to reflect thenon-configuration-ready mode causes the secure storage device 110 to beinaccessible by the configurator application in the host 120 for a newconfiguration connection subsequent to the terminated connection. Forexample, a new configuration session subsequent to the currentconfiguration session is not permitted when the secure storage device110 is in a non-configuration-ready mode. In one or more aspects, thesecurity controller 258 (or a microcontroller therein) may generate andprovide a new instruction to lock access for configuration when theconfiguration is complete and/or the flag setting has been set toindicate the non-configuration-ready mode. As such, the secure storagedevice 110 is prevented from being configured by the host. In one ormore implementations, the device 110 needs to be reset to aconfiguration-ready mode (e.g., by nullifying or erasing any previousconfiguration data and by creating a new data transfer encryption key,which can be viewed as erasing any encrypted data previously stored inthe memory 232) by a user before the device 110 can be configured againby the configurator application 222.

In another implementation, once a secure storage device 110 isconfigured by a host (e.g., by the configurator application), the deviceis prevented from being re-configured by the host (e.g., by theconfigurator application) at a later time. In one example, a securestorage device 110 does not provide a user-set configuration-ready mode;hence, the secure storage device can be configured by a host only oncein an out-of-box mode.

In one or more implementations, each configuration encryption key(s) isgenerated (e.g., by the security controller 258 (or a microcontrollertherein) and the configurator application 222) for each configurationsession and for each secure storage device 110 to be configured using ahost 120. In one or more implementations, when a configuration sessionis terminated, such configuration encryption key(s) are prevented frombeing stored (and thus are not stored) on the host 120 or the securestorage device 110. For example, such configuration encryption key(s)are erased (e.g., replaced with null key(s)) when a configurationsession is terminated. This process improves security associated withthe secure storage devices.

While the secure storage device 110 operates in anon-configuration-ready mode (e.g., a normal operating mode), if a userdesires to place the secure storage device 110 back into aconfiguration-ready mode (which may be referred to as a user-setconfiguration-ready mode for this instance), the user can press thebutton(s) on the physical input device 246 designated to place thedevice 110 into a configuration-ready mode, and this causes the securitycontroller 258 (or a microcontroller therein) to set the PIN(s) storedin the device 110 to “null” PIN(s).

In one or more implementations, when the user presses the button(s)designated to place the device 110 into a configuration-ready mode, thiscauses the security controller 258 (or a microcontroller therein) toreset the encryption key(s), which are stored in the device 110, to newencryption key(s), which may be viewed as crypto-erasing the device 110(or the memory 232).

In one or more implementations, when the user presses the button(s)designated to place the device 110 into a configuration-ready mode, thiscauses the security controller 258 (or a microcontroller therein) to setthe indication (e.g., a flag in a memory) to indicate that the securestorage device 110 is in a configuration-ready mode. In one or moreaspects, a configuration-ready mode indicates that the secure storagedevice 110 is allowed to communicate with the host 120 to configure thesecure storage device 110.

The description below illustrates examples of a process for setting asecure storage device 110 back into a configuration-ready mode.

The security controller 258 (or a microcontroller therein) may receiveuser input via the physical input device 246 when the secure storagedevice 110 is determined not to be in the configuration-ready mode. Forexample, the user input may include a sequence of control signals forcausing removal/replacement of at least a part of the configuration datafrom the secure storage device 110 (e.g., setting the PIN(s) to “null”PIN(s)). In one or more implementations, since the secure storage deviceis no longer reconfigurable by the host 120 when the secure storagedevice is not in the configuration-ready mode, the physical input device246 on the secure storage device 110 may be the remaining means toprovide access to the secure storage device 110.

In this respect, a user of the secure storage device may activate aconfiguration-ready reset feature of the secure storage device 110 byentering a known (or predetermined) entry or sequence of entries via thephysical input device 246. For example, the user may press one or morekeys or buttons on the physical input device 246 at once for apredefined period of time to trigger the configuration-ready resetfeature. In another example, a user may provide a biometric input viathe physical input device 246 to trigger the configuration-ready resetfeature when the physical input device 246 is an embedded sensor. In yetanother example, a user may provide a touch input sequence (e.g., amulti-tap input, a predefined gesture pattern, or the like) via thephysical input device 246 to trigger the configuration-ready resetfeature when the physical input device 246 is an embedded touchscreen.

In one or more implementations, the security controller 258 (or amicrocontroller therein) may cause determining whether aconfiguration-ready reset operation in the secure storage device 110,based on the received user input, is complete. For example, the securitycontroller 258 (or a microcontroller therein) may scan the securestorage device 110 and confirm that any prior security information is nolonger present or valid. Further, the security controller 258 (or amicrocontroller therein) may cause a crypto-erase operation of anystored encryption key (e.g., the data transfer encryption key). In someexamples, the security controller 258 (or a microcontroller therein),using, for example, an entropy generator, generates a new randomizedencryption key(s) (e.g., a handshake key(s)) as part of the crypto-eraseoperation. The secure storage device 110 then stores an indication thatthe secure storage device 110 is in a configuration-ready mode when theconfiguration-ready reset operation is determined to be complete. Inthis respect, the security controller 258 (or a microcontroller therein)may modify the flag setting to indicate the configuration-ready mode(e.g., setting the configuration-ready flag).

In one or more implementations, a security controller 258 may includemultiple microcontrollers and may also include multiple memories.

In one or more implementations, each of the multiple microcontrollers ofthe security controller 258 may perform one or more of the variousfunctions of the security controller 258 described herein, such asencrypting data to the memory 232, decrypting data from the memory 232,utilizing an encryption engine and a data transfer encryption key forencrypting or decrypting data, performing functions of an entropygenerator (which may be a hardware random number generator used increating a handshake key(s), a configuration encryption key(s), or adata transfer encryption key(s)), generating a new data transferencryption key (for an out-of-box mode or for a user-setconfiguration-ready mode), generating a new handshake key(s) (for anout-of-box mode or for a user-set configuration-ready mode), generatinga configuration encryption key, setting the configuration data to nullconfiguration data (for an out-of-box mode or for a user-setconfiguration-ready mode), setting or modifying an indication (e.g., aflag) to indicate whether a secure storage device 110 is in aconfiguration-ready mode, determining whether a secure storage device110 is in a configuration-ready mode, initiating a configuration process(or session) with a host, terminating a configuration process (orsession) with the host, causing or facilitating the identifierinformation (e.g., a product ID and a vendor ID) and/or otherenumeration information associated with a secure storage device 110 tobe transmitted to the host 120, providing the indication whether asecure storage device 110 is in a configuration-ready mode fortransmission to the host 120, performing a handshake process with ahost, decrypting configuration data from the host, facilitating storingof configuration data, detecting that a secure storage device 110 (orits component(s)) is powered on, communicating with or receiving inputfrom the physical input device 246, and/or communicating with orproviding output to the physical output device 244.

In one example, one microcontroller may perform one or more functions ofthe security controller 258 described herein. In another example,multiple microcontrollers may perform one of the functions of thesecurity controller 258 described herein.

The microcontrollers within the security controller 258 may havedifferent security protection levels. For example, a firstmicrocontroller may have a security level that is higher than thesecurity level of a second microcontroller, and the secondmicrocontroller may have a security level that is higher than thesecurity level of a third microcontroller. In one or moreimplementations, some or all of the microcontrollers within the securitycontroller 258 may have the same security protection level or differentsecurity protection levels.

The microcontrollers within the security controller 258 may be coupled,directly or indirectly, to each other using communication links, such asbidirectional communication links. These microcontrollers may becoupled, directly or indirectly, to the physical input device 246, thephysical output device 244, the memory 232, and the communicationsmodule 238. In one example, one microcontroller may provide instructionsand/or data (e.g., instructions and/or data generated or handled by themicrocontroller or stored by the microcontrollers or its associatedmemory(ies)) to the host via another microcontroller and thecommunications module 238. In one example, one microcontroller mayreceive instructions and/or data (e.g., instructions and/or datagenerated or handled by the host or stored by the host or its associatedmemory(ies)) via another microcontroller and the communications module238. In other examples, one or more microcontrollers within the securitycontroller 258 are coupled directly to one or more othermicrocontrollers but are not coupled directly to yet other one or moremicrocontrollers.

In one or more examples, the security controller 258 or one or moremicrocontrollers therein may be coupled to the physical input device 246and the physical output device 244. In one or more examples, thesecurity controller 258 or one or more microcontrollers therein mayreceive an input (e.g., one or more PINs, a configuration-ready resetsignal or other user input) from the physical input device 246. In oneor more examples, the security controller 258 or one or moremicrocontrollers therein may provide an output (e.g., a signal to emit alight indicating a configuration-ready mode) to the physical outputdevice 244.

In one or more examples, each or some of the microcontrollers mayinclude multiple microcontrollers. In one or more examples, each or someof the microcontrollers may include an encryption engine.

In one or more implementations, a security controller 258 may partitionits functions differently using a different number of microcontrollers(e.g., two, three, or more numbers of microcontrollers). Suchmicrocontrollers may have the same or different security levels. In oneexample, a security controller 258 may be a single microcontroller.

In one or more implementations, a secure storage device 110 stores anencryption key(s) (e.g., a data transfer encryption key(s)),configuration data, and an indication (e.g., a flag) that indicateswhether a secure storage device 110 is in a configuration-ready mode. Inone or more implementations, the encryption key(s) may include ahandshake key(s). In one or more implementations, the encryption key(s)may include a configuration encryption key.

In one or more implementations, a local memory 240 may store some or allof the encryption key(s), configuration data, and an indication of theconfiguration-ready mode. In one or more implementations, one or morememories within the local memory 240 may store some or all of theforegoing.

Memories may have different security levels. In one example, one or someof the foregoing information may be stored in a memory having a highsecurity level. In one example, other information may be stored in amemory(ies) having a lower security level. In another example, all ofthe foregoing information may be stored in a memory(ies) having the samesecurity level. In another example, the forgoing information may bedivided up and stored in different memories having different securitylevels. In one or more examples, encryption keys may be stored in onememory or multiple different memories.

When the local memory 240 has multiple memories and the securitycontroller 258 has multiple microcontrollers, a memory may be associatedwith its microcontroller. For example, a microcontroller (or eachmicrocontroller) may have its associated memory(ies) for storinginstructions/data generated, used, provided, or received by therespective microcontroller.

In one example, the memory(ies) associated with one microcontroller mayhave a higher security level than the memory(ies) associated withanother microcontroller. In one or more other examples, some or all ofthe memories within the local memory 240 may have the same securityprotection level or different security protection levels.

In one implementation, configuration data may be stored in a memoryassociated with a microcontroller that decrypts configuration data fromthe host. In another implementation, configuration data may be stored inanother memory within the local memory 240 or a secure storage device110. In one or more examples, different parts of the configuration datamay be stored in different memories.

In one implementation, an indication of the configuration-ready mode maybe stored in a memory associated with a microcontroller that determineswhether a device 110 is in a configuration-ready mode. In anotherimplementation, the indication may be stored in another memory withinthe local memory 240 or a secure storage device 110.

In one or more implementations, the memory 232 or a portion therein maystore some or all of the encryption key(s), configuration data, and theindication of the configuration-ready mode.

An encryption key may include one or more keys. An encryption key may bereferred to as an encryption/decryption key or a decryption key as thekey may be used to encrypt and/or decrypt data. A handshake key mayinclude one or more keys (or one or more encryption keys). An encryptionengine may encrypt outgoing messages and/or decrypt incoming messages.An encryption engine may be referred to as an encryption/decryptionengine or a decryption engine as the encryption engine can encryptand/or decrypt data.

FIG. 3A illustrates an example of a process 300 for configuration ofsecure storage devices using the example host of FIG. 2. While FIG. 3Ais described with reference to FIG. 2, it should be noted that theprocess steps of FIG. 3A may be performed by other systems. Aconfigurator application 222 that runs on a computer, such as a personalcomputer (PC), can configure storage devices via a communicationinterface such as a USB port. The configurator application 222 candeploy one device or hundreds of secure storage devices. A multitude ofsecure storage devices can be configured and deployed concurrently (orsimultaneously) using the configurator application 222.

The process 300 begins when a secure storage device (e.g., 110) is in aconfiguration-ready mode and ready for configuration by the host 120.Resulting from the configuration-ready mode in the secure storage device110, the secure storage device 110 becomes visible to the host 120 onthe communication bus 130 and accessible to receive configuration datafrom the host 120 via the communication bus 130.

The process 300 utilizes a configurator application 222, which isuser-friendly. Using the configurator application 222, a user may loadsecure storage device information (e.g., serial numbers or otherinformation) and settings ahead of time, create configuration profiles,including policies and groups, start plugging in secure storage devicesinto the host 120, and then auto-configure these secure storage devices.Alternatively, a user can have the configurator application 222 performthese functions as the secure storage devices are plugged into the host120 and enter the secure storage device information and settings one ata time.

Subsequently, in step 304, the processor 212 of the host 120, e.g., theconfigurator application 222, generates a configuration profile. Forexample, the configuration profile may include profile data such assecurity information (e.g., PINs for administrators and/or users, etc.)and/or configuration setting(s) (e.g., auto-lock, lock-override,self-destruct, etc.). In one or more implementations, once aconfiguration profile is created, it can be saved and applied again onone or more additional secure storage devices without having tore-create the profile.

Next in step 306, the processor 212 facilitates establishment of asecure communication channel with the secure storage device 110 via thecommunications module 218 and the communications module 238. The securecommunication channel is a conduit for allowing a secure exchange ofcommunications between the host 120 and the secure storage device 110,including a secure handshake and provision of encrypted configurationdata from the host 120.

In step 308, the processor 212, e.g., the configurator application 222,applies the configuration profile to the secure storage device(s) 110.The configuration data may include, or may refer to, the configurationprofile being applied to the secure storage device(s) 110. Theconfiguration profile is then stored in the secure storage device 110accessible to the security controller 258 (or a microcontroller therein)of the secure storage device 110. The configuration profile may beencoded with a randomly-generated encryption key that is exclusive tothe secure storage device 110. After a configuration file is applied,the processor 212, e.g., the configurator application 222, creates a logof the secure storage device's product information (e.g., a serialnumber) along with the actual configuration profile for future queriesand stores the log in an encrypted database associated with this host120 (e.g., the memory 220).

Subsequently, in step 310, the configuration of the storage device 110is completed. In this respect, the indication of the configuration-readymode is removed from the communication bus 130 (e.g., replaced by anindication that the device 110 is not in a configuration-ready mode) andaccess to the secure storage device 110 for configuration via thecommunication bus 130 is blocked. Accordingly, once configured, thesecure storage drive 110 is no longer available to the configuratorapplication 222. The device 110 needs to be reset to aconfiguration-ready state by a user before the device 110 can beconfigured once again by the configurator application 222.

Next, in step 312, the secure storage device is configured and ready tostore secure data in the memory 232 of the secure storage device 110.

FIG. 3B illustrates an example of a process 320 of a communicationexchange between the secure storage device 110 and host 120 of FIG. 2for configuration of secure storage devices.

The process 320 begins by proceeding from the start step to step 321when one or more secure storage devices 110 are connected to the host120. In this respect, the one or more secure storage devices areconnected to a data terminal (e.g., including a communication bus 130 inFIG. 1) that can host an array of secure storage devices 110. The dataterminal may include a powered USB bus. In other aspects, the dataterminal serves as a passive conduit (or dummy terminal) such that powerbeing applied through the data terminal may originate from the host 120that is electrically coupled to the data terminal.

Next, in step 322, the processor 212 of the host 120, e.g., theconfigurator application 222, determines whether each of the one or moresecure storage devices 110 is in a configuration-ready mode (e.g., usingan indication (or the value of a flag) supplied by each secure storagedevice). At power-up, the security controller 258 (or a microcontrollertherein) of each secure storage device 110 may initiate a sub-processthat checks for the current mode of operation of the correspondingsecure storage device 110, including checking to see that the securestorage device is in a configuration-ready mode.

Subsequently, in step 323, the processor 212 of the host 120, e.g., theconfigurator application 222, identifies secure storage device(s) 110that are determined to be in a configuration-ready mode when theconfigurator application 222, in step 322, determines that the securestorage device(s) 110 are in the configuration-ready mode.Alternatively, the processor 212, e.g., the configurator application222, terminates the process 320 by proceeding to the end step when nosecure storage devices are determined to be in the configuration-readymode in step 322.

In step 324, the processor 212, e.g., the configurator application 222,selects a configuration profile for at least one secure storage device110 identified to be in the configuration-ready mode. The configurationprofile may be selected in response to a user of the configuratorapplication 222 providing a user selection of the configuration profileprovided for display via a user interface of the configuratorapplication 222.

Next, in step 325, the processor 212, e.g., the configurator application222, initiates configuration of the at least one secure storage devicewith the selected configuration profile. In this respect, the processor212, e.g., the configurator application 222, may gather theconfiguration data corresponding to the selected configuration profilefor provisioning to the secure storage device 110.

In step 326, the processor 212, e.g., the configurator application 222,performs a handshake process with the at least one secure storage device110. Subsequently, in step 327, the processor 212, e.g., theconfigurator application 222, facilitates establishment of aconfiguration encryption key(s) between the host 120 and the at leastone secure storage device 110. Next, in step 328, the processor 212,e.g., the configurator application 222, encodes the selectedconfiguration profile using the configuration encryption key.

In step 329, the processor 212, e.g., the configurator application 222,sends the encoded configuration profile to the at least one securestorage device 110 to facilitate decryption of the encoded configurationprofile by the secure storage device 110. Using the configurationencryption key established in step 327, the security controller 258 (ora microcontroller therein) can decode/decrypt the received configurationdata.

Subsequently, in step 330, the processor 212, e.g., the configuratorapplication 222, stores the applied configuration profile with an indexassociated with the at least one secure storage device 110. Next, instep 331, the processor 212, e.g., the configurator application 222,facilitates terminating the connection (e.g., terminating theconfiguration session) between the host 120 and the at least one securestorage device 110 configured with the configuration profile.

When there are multiple secure storage devices that are in aconfiguration-ready mode, steps 323 to 331 are performed for each ofthose multiple secure storage devices, where the host, e.g., theconfigurator application 222, provides to each of the secure storagedevices a corresponding configuration profile. One configuration profilemay be applied to one or multiple secure storage devices. For example,when a first secure storage device is the same type as a second securestorage device (e.g., a certain flash memory type), the sameconfiguration profile can be used for both storage devices. In anotherexample, even if two storage devices are of the same type, differentconfiguration profiles may be utilized for such devices.

FIG. 3C illustrates an example of a process 340 for establishing aconnection to the example host 120 using the example secure storagedevice 110 of FIG. 2. While FIG. 3C is described with reference to FIG.2, it should be noted that the process steps of FIG. 3C may be performedby other systems.

In one or more examples, steps 341-345 of FIG. 3C may relate to step 321of FIG. 3B, steps 342-346 of FIG. 3C may relate to steps 322 and 323 ofFIG. 3B, and step 347 of FIG. 3C may relate to steps 325, 326 and 327 ofFIG. 3B.

The process 340 begins in step 341 when the security controller 258 (ora microcontroller therein) of the secure storage device 110, forexample, detects that the secure storage device 110 is powered on. Inone or more implementations, the secure storage device 110 is appliedwith power from the host 120 via the communication bus 130. Next, instep 342, the security controller 258 (or a microcontroller therein)accesses the secure storage device 110 or one of its memories todetermine a current mode of operation of the secure storage device 110.Step 342 may be performed before, after or concurrently with step 341.

In step 343, the security controller 258 (or a microcontroller therein)determines that the current mode of operation is a configuration-readymode based on the access of the memory. Step 343 may be performedbefore, after or concurrently with step 341. In step, 344, the securitycontroller 258 (or a microcontroller therein) sends an instruction toinitiate communication on the communication bus 130 (e.g., via anothermicrocontroller in the security controller 258). In one or moreimplementations, the instruction includes an indication of theconfiguration-ready mode.

Turning to the host 120, in step 345, the host 120 detects presence ofthe secure storage device 110 and obtains identifier information of thesecure storage device 110 via the communication bus 130. In step 346,the host 120 determines that the secure storage device 110 is in theconfiguration-ready mode based on the indication provided by thesecurity controller 258 (or a microcontroller therein) that the device110 is in the configuration-ready mode.

Turning back to the secure storage device 110, in step 347, the securestorage device 110 (together with the host 120) facilitatesestablishment of a secure communication channel between the host 120 andthe secure storage device 110 to configure the secure storage device110. In this respect, the secure storage device 110 and the host 120establish configuration encrypting keys for encrypting messages(including the configuration data) to the secure storage device 110 forthe configuration process.

FIG. 3D illustrates an example of a process 350 for reconfiguration ofthe example secure storage device in FIG. 2. While FIG. 3D is describedwith reference to FIG. 2, it should be noted that the process steps ofFIG. 3D may be performed by other systems.

In one or more examples, step 352 of FIG. 3D may relate to step 322 ofFIG. 3B and step 343 and 346 of FIG. 3C, step 353 of FIG. 3D may relateto step 325 of FIG. 3B, and step 354 of FIG. 3D may relate to step 331of FIG. 3B.

The process 350 can be applicable to a secure storage device 110 thathas been previously configured (e.g., the device 110 is in anon-configuration-ready mode, where the device 110 already contains avalid PIN(s) to unlock (or to facilitate unlocking) the device afterbeing locked). The process 350 begins by proceeding from the start stepto step 351 when the security controller 258 (or a microcontrollertherein) of the secure storage device 110 resets the secure storagedevice 110 into a configuration-ready mode.

In one or more implementations, the secure storage device 110 (e.g., thesecurity controller 258 or a microcontroller therein) receives an inputsuch as a configuration-ready reset signal when an input at the physicalinput device 246 (e.g., one or more key entries on the keypad) isentered that triggers setting the secure storage device 110 into aconfiguration-ready mode, including (i) “nullifying” any configurationdata (e.g., a reset of the security information and other configurationsetting(s)), (ii) creating new encryption key(s) (e.g., a new datatransfer encryption key associated with the data transfer to/from amemory (e.g., 232)), and (iii) a reset of the flag setting to indicatethat the secure storage device 110 is in the configuration-ready mode.The secure storage device 110 may receive a configuration-ready resetsignal during a non-configuration-ready mode. In one or moreimplementations, the secure storage device 110 may receive aconfiguration-ready reset signal while the secure storage device 110 isin a locked state. In another implementation, the secure storage device110 may receive a configuration-ready reset signal while the securestorage device 110 is in an unlocked state.

In one or more other implementations, when a secure storage device 110is in a non-configuration-ready mode (e.g., the device contains a validPIN) and is unlocked (e.g., a matching PIN has been entered on thephysical input device 246), the secure storage device 110 (e.g., thesecurity controller 258 or a microcontroller therein) may receive aninput such as a configuration-ready reset signal via the communicationbus from a host 120, and this receipt of the configuration-ready resetsignal can initiate resetting the secure storage device 110 into aconfiguration-ready mode, including (i) “nullifying” any configurationdata, (ii) creating new encryption key(s) (e.g., a new data transferencryption key), and (iii) a reset of the flag setting to indicate thatthe secure storage device 110 is in the configuration-ready mode.

Subsequently, in step 352, the security controller 258 (or amicrocontroller therein) determines that the device is in theconfiguration-ready mode. In this respect, the security controller 258(or a microcontroller therein) may scan the secure storage device 110and determine that the stored flag setting indicates theconfiguration-ready mode. In this respect, the secure storage device 110may allow the security controller 258 (or a microcontroller therein) toprovide the identifier information (e.g., product ID and vendor ID) andthe indication of the configuration-ready mode via the communicationmodule 238 for provision to the communication bus 130.

Next in step 353, the security controller 258 (or a microcontrollertherein) initiates configuration of the secure storage device 110. Inresponse to understanding that the secure storage device 110 is in a“configuration-ready state” based on the indication of theconfiguration-ready mode, the host 120 can begin a secure transfer ofnew configuration data to the secure storage device 110. In step 354,the security controller 258 (or a microcontroller therein) can send aninstruction to terminate the connection to the host 120 (e.g., end thisre-configuration session) when the re-configuration of the securestorage device 110 is complete.

FIG. 3E illustrates an example of a process 360 for creatingconfiguration profile data using the example host in FIG. 2. While FIG.3E is described with reference to FIG. 2, it should be noted that theprocess steps of FIG. 3E may be performed by other systems.

In one or more examples, most of the steps of the process 360 may beperformed, for instance, in connection with step 324 of FIG. 3B or priorto step 321 of FIG. 3B.

The process 360 begins in step 361 when the processor 212 of the host120, for example, loads the configurator application 222 on the host120, and the host 120 receives an input from a user using the inputdevice 216 to initiate generating one or more configuration profiles.

Subsequently, in step 362, the processor 212, e.g., the configuratorapplication 222, generates one or more configuration profiles forconfiguring the secure storage device 110. Next in step 363, theprocessor 212, e.g., the configurator application 222, provides one ormore user interface controls via the configurator application 222 formanaging the one or more configuration profiles.

In step 364, the processor 212, e.g., the configurator application 222,stores the one or more configuration profiles, e.g., encoded with anencryption key, in a memory associated with the host 120. In one or moreimplementations, the one or more configuration profiles are stored asconfiguration profile data 260 in the memory 220 or a memory associatedwith the host.

FIG. 3F illustrates an example of a process 370 for querying storedconfiguration profile data using the example host of FIG. 2. While FIG.3F is described with reference to FIG. 2, it should be noted that theprocess steps of FIG. 3F may be performed by other systems.

The process 370 begins by proceeding from start step to step 371 whenthe processor 212 of the 120, e.g., the configurator application 222,receives a search query identifying a request to retrieve, from a memory(e.g., 220), the configuration profile data 260 of a configured device(e.g., secure storage device 110). For example, a user may enter aserial number of a storage device.

Subsequently, in step 372, the processor 212, e.g., the configuratorapplication 222, retrieves the configuration profile data 260 from thememory (e.g., 220) associated with the host 120. Next in step 373, theprocessor 212, e.g., the configurator application 222, provides theretrieved configuration profile data 260 for display via the outputdevice 214 of the host 120.

In one or more implementations, the process 370 does not involveaccessing any secure storage device that is already configured (e.g., adevice that contains a valid PIN(s)). The process 370 does not query anysecure storage device that is configured. A secure storage device 110 isnot connected to the host 120 during the process 370, and the host 120does not access any secure storage device 110 that is configured. Whenthe host 120 receives a query, it merely accesses its own memory (e.g.,220) or another memory that is accessible by the host where theconfiguration profile data is stored. However, none of these memories isany memory within a secure storage device that has been configured.Hence, the process 370 does not involve assessing or retrieving any dataor information (e.g., any configuration data) from any secure storagedevice that is configured and locked.

FIGS. 4A through 4E illustrate examples of a host user interface of aconfigurator application 222 that can be utilized by a host, such as theexample host of FIG. 2. FIG. 4A illustrates an example of a userinterface 400 of the configurator application 222 running on the host120 for selecting one of a plurality of sub-processes in theconfiguration of the secure storage device 110. FIG. 4B illustrates anexample of a user interface 420 of the configurator application 222 forcreating configuration profiles. FIG. 4C illustrates an example of auser interface 440 of the configurator application 222 for viewing thesecurity information and other settings of configuration profiles beforeapplying a selected configuration profile to the secure storage device110. FIG. 4D illustrates an example of a user interface 460 of theconfigurator application 222 for reviewing saved configuration profilesand managing the configuration profiles. FIG. 4E illustrates an exampleof a user interface 480 of the configurator application 222 for queryingone or more of the configuration profiles hosted by the configuratorapplication 222.

Specifically, FIG. 4A illustrates the user interface 400 identifyingeach of the sub-processes with an individual graphical element andassociated description. In one or more implementations, the graphicalelement for each of the sub-processes is associated with a userinterface control for enabling a user of the configurator application222 to launch the sub-process via the configurator application 222. InFIG. 4A, the user interface 400 lists a first sub-process 420, a secondsub-process 440, a third sub-process 460 and a fourth sub-process 480.The user interface 400 is not limited to the sub-processes illustratedin FIG. 4A, and a different number of sub-processes may be provided fordisplay via the user interface 400 depending on implementation.

In one or more implementations, the first sub-process (e.g., 420)relates to creating and storing of customized secure storage devicesecurity parameters (e.g., PINs for an administrator, a user andrecovery) and other configuration setting(s) (see, e.g., items 425-431in FIG. 4B). The second sub-process (e.g., 440) may relate to theapplication of a single configuration profile to multiple secure storagedevices 110 simultaneously. The third sub-process (e.g., 460) may relateto providing access to an overview of the stored configuration profilesincluding access to management permissions to modify the storedconfiguration profiles. The fourth sub-process 480 may relate to thequerying of the configuration profiles stored in a memory associatedwith a host.

In one or more examples, the first sub-process (e.g., 420) may relate tostep 362 of FIG. 3E, the second sub-process (e.g., 440) may relate tostep 324 of FIG. 3B, the third sub-process (e.g., 460) may relate tostep 363 of FIG. 3E, and the fourth sub-process 480 may relate to FIG.3F.

FIG. 4B provides an example of the user interface 420 for creating aconfiguration profile. A configuration profile may be used as a masterconfiguration profile. A configurator application 222 thus allows a userof the configurator application to enter configuration data using a userinterface such as the user interface 420.

The user interface 420 includes a profile setting setup feature 421, aPIN setup method feature 422A/422B, an administrator PIN setup feature433, a user PIN setup feature 423, a recovery PIN setup feature 424, anauto-lock setup feature 425, a brute force attempt setup feature 426, aself-destruct setup feature 427, a lock-override setup feature 428, avisual indicator setup feature 429, a device format setup feature 430,an upload control feature 431, and a user interface control feature 432.FIG. 4B is not limited to the number of setup features illustrated inFIG. 4B, and a different number of setup features may be provided fordisplay via the user interface 420 depending on implementation.

A configurator application 222 can utilize the areas shown in FIG. 4Band configure a profile setting, a PIN setup method, various PINs, anauto-lock feature, a brute force attempt feature, a self-destructfeature, a lock-override feature, a visual indicator feature, a deviceformat feature, an upload control, and a user interface control. Aconfigurator application 222 is not limited to the features describedand can include additional features or less number of features.

In the illustration, the profile setting setup feature 421 may includesubfields for a device type, a profile name, and the minimum PIN length.In order to set up a configuration profile, one of the listed devicetypes may be selected. This allows creating different securityinformation and configuration settings for different device types. Forexample, a first type of secure storage device may use only one userPIN, whereas a second type of secure storage device may use four PINs.The minimum PIN length setting may force the length of all PINs to havea minimum digit length, including PINs for a reset or added manually.

The PIN type setup feature 422A/422B includes options to generate PINsautomatically by a configurator application or require a user to enter aPIN(s) (e.g., via a keypad on the physical input device 246). The PINtype setup feature allows selecting one or more features ofauto-generate administrator PIN, auto-generate user PIN(s),auto-generate recovery PIN(s) or activate user forced enrollment.

In one or more implementations, a user forced enrollment is a modewhereby the secure storage device 110 has already been programmed andhas an administrator PIN but requires that the user set up a new PIN(e.g., new user PIN) to access the secure storage device 110. Whenforced enrollment is activated, the output device 244 may provide one ormore visual indications indicating that a new PIN needs to be programmedmanually to gain access to the secure storage device 110.

The administrator PIN setup feature 433 includes an option to enter anadministrator PIN. The user PIN setup feature 423 includes an option toenter a user PIN. The recovery PIN setup feature 424 includes an optionto enter a recovery PIN(s). The user PIN (e.g., 423) and theadministrator PIN (e.g., 433) can be configured independently, such thatthe secure storage device 110 may be unlocked with the administrator PINor a user PIN. Each auto-generated PIN (e.g., an auto-generatedadministrator PIN, an auto-generated user PIN and each auto-generatedrecovery PIN) created for each secure storage device configured with theprofile may be unique. In one or more implementations, theauto-generated PINs are encrypted and stored in a data file as part ofthe configuration profile data 260. In some implementations, each PIN(e.g., an administrator PIN, a user PIN and a recovery PIN) may bemanually set. When manually set, the PIN does not change when loadedacross all the secure storage devices that are configured with thisconfiguration profile.

The recovery PIN setup feature 424 includes options to manually enteruser-generated recovery PINs including option to enable the recovery PINfor launching the user-forced enrollment. In this example, up to 4recovery PINs may be created. The recovery PIN may not be an actual PINthat unlocks the secure storage device 110, but rather puts the securestorage device 110 into a state of user-forced enrollment where a newuser PIN can then be created. The recovery PINs allows a secure storagedevice 110 that is already configured and has secure data stored thereonto be given to an operator with a recovery PIN such that the operator isallowed to set his or her own user PIN while keeping the secure datasecured.

The auto-lock setup feature 425 can set a predefined period of time ofinactivity that causes the secure storage device 110 to lock. The securestorage device 110, however, does not lock when data is being writteninto the memory 232.

The brute force attempt setup feature 426 can set the number ofincorrect attempts before the secure storage device 110 erases/replacesthe encryption key (e.g., crypto-erase), thus making the data previouslystored on the secure storage device 110 unrecoverable.

The self-destruct setup feature 427 allows both an administrator and auser to set a self-destruct PIN when the self-destruct feature isenabled. During a normal operation (e.g., not in the configuration-readymode), when the self-destruct PIN is entered, the encryption key for thememory 232 may be reset (e.g., reset to a “new” encryption key),rendering the encrypted data previously stored on the memory 232unrecoverable. In some aspects, the self-destruct PIN replaces any priorexisting administrator PIN and becomes the new administrator PIN. It isnoted that the self-destruct feature does not place a secure storagedevice 110 into a configuration-ready mode, as (i) theconfiguration-ready mode flag is not set, and there is a valid PINstored in the secure storage device (i.e., the self-destruct PIN becomesthe new administrator PIN) that can be used to unlock the device 110after the device is locked.

The lock-override setup feature 428 allows the secure storage device 110to stay unlocked during a USB re-enumeration procedure. The lockoverride may be enabled during a reboot sequence, and using the securestorage device 110 as a boot drive. The secure storage device 110 mayremain unlocked in the lock override state as long as the secure storagedevice 110 remains connected (or plugged) into a USB port. When a USBconnection is lost (e.g., the secure storage device 110 is unpluggedform the USB port), the secure storage device 110 may become locked.

The visual indicator setup feature 429 may confirm a keypad entrysuccess by causing the output device 244 to provide an output that isrecognizable by a user (e.g., light emitted by one or more LEDs inresponse to a key press, such as a blinking light).

If the device format setup feature 430 is enabled, then after the securestorage device 110 is configured, the device can unlock and reformat(e.g., reformat the memory 232) so that data files can be written intothe memory 232.

The upload control 431 provides an option to upload one or more datafiles from the host 120, for example, as part of the drive formatfeature. It is noted that data files may be any type of files (e.g.,program files, images, videos, audios, documents, etc.).

The user interface control 432 provides a control to confirm creation ofthe configuration profile, thereby storing the configuration profile ina memory of the host 120 (e.g., as part of the configuration profiledata 260).

When the host 120 provides, to the secure storage device 110, encryptedconfiguration data, such as the security information (e.g., theadministrator, user and recovery PINs) and other configurationsetting(s) (e.g., the settings for the device features 425-430), thesecurity controller 258 (or a microcontroller therein) may decrypt theconfiguration data using the configuration encryption key and store theconfiguration data in the secure storage device 110.

In one or more implementations, configuration data may include securityinformation and other configuration setting(s). The security informationmay include, for example, an administrator PIN (see, e.g., 433), a userPIN (see, e.g., 423), one or more recovery PINs (see, e.g., 424), and/ora self-destruct PIN (see, e.g., 427). Other configuration settings mayinclude, for example, an auto-lock setting (see, e.g., 425), a bruteforce attempts setting (see, e.g., 426), a self-destruct setting (see,e.g., 427), a lock-override setting (see, e.g., 428), a key press LEDindicator setting (see, e.g., 429), a drive format setting (see, e.g.,430), and/or an add files setting (see, e.g., 431). The default settingsof these configuration setting may be, for example, as follows:

default auto-lock setting: disable

default brute force attempts setting: 20

default self-destruct setting: disable

default lock-override setting: disable

default key press LED indicator setting: disable

default drive format setting: NTFS

default add files setting: disable

In one or more implementations, these PINs and configuration settingsare examples, and configuration data is not limited to these examples.In one or more implementations, configuration data may include only someof these, does not include any of these, and/or may include other typesof security information and/or data.

FIG. 4C provides an example of the user interface 440 for viewing aconfiguration profile and applying a selected configuration profile tothe secure storage device 110. The user interface 440 includes a searchquery input feature 441, a search query result 442, a configurationprofile output report 443, and a user interface control 444. The userinterface 440 allows a user of the configurator application 222 toreview the settings for each secure storage device before having theconfiguration profile applied to the secure storage device 110.

FIG. 4D provides an example of the user interface 460 for managing theconfiguration profiles. The user interface 460 includes a configurationprofile interface 461, a configuration profile index hierarchy 462(e.g., by device type), and a user interface control 463. The userinterface 460 allows a user of the configurator application 222 toreview stored configuration profiles (e.g., stored in a memory of ahost), edit the profiles and manage the profiles. This feature does notaccess any secure storage device that has been configured.

FIG. 4E provides an example of the user interface 480 for querying oneor more of the configuration profiles. The user interface 480 includes asearch query input field 481 and a search query results page 482. In oneor more implementations, the user interface 480 allows a user of theconfigurator application 222 to lookup the configuration settings thatwere originally programmed on a secure storage device (e.g., 110) byaccessing a memory of the host 120 without accessing the secure storagedevice that has been configured.

The descriptions below illustrate examples of various features that maybe implemented by a secure storage device 110 (for example, inconjunction with a configurator application 222 for some features) inone or more examples.

In one or more implementations, a secure storage device 110 may beimplemented with and include one or more of the following features: ahardware encrypted USB 3.0 flash drive; on-the-fly hardware encryption;software-free installation and operation; completely cross-platformcompatible in one or more implementations; high-quality rugged aluminumhousing; water and dust resistant; embedded 7-16 digit PINauthentication; no security parameters shared with hosts in one or moreimplementations; programmable minimum PIN length; an administrator modefor secure deployment; independent user and administrator PINs; recoveryPINs in case of a forgotten PIN; an administrator forced enrollment atfirst use; a user forced enrollment option; a tough epoxy internalfilling for physical-attack protection; a brute-force protection; aself-destruct PIN feature; compatible with any operating system (OS)such as Windows®, Mac® and Linux; super-fast USB 3.0; 10× faster thanUSB 2.0; a variable timing circuit(s); a lock-override mode; adrive-reset feature; an auto-lock feature; two read-only modes; and/orconfigurable. These features are examples, and the subject technology isnot limited to these examples.

In one or more implementations, a secure storage device 110 may beimplemented with and include one or more of the following features toprovide advanced data protection. These features are examples, and thesubject technology is not limited to these examples.

-   -   One or more implementations that are software-free,        cross-platform compatible, configurable, and having a host of        high-level security features packed into a flashkey.    -   Military grade hardware encryption: In one or more        implementations, a secure storage device encrypts all data        (e.g., all data to a mass storage memory within the secure        storage device) on-the-fly.    -   Software-free design: In one or more implementations, a secure        storage device can be used right out of the box—no software, no        drivers, no updates are needed. A secure storage device can be        utilized where no separate input device (e.g., a keyboard) is        present. In one or more implementations, a secure storage device        is completely cross-platform compatible (e.g., PCs, Mac®, Linux,        or any OS with a powered USB port and a storage file system),        and a secure storage device excels virtually anywhere.    -   Host-free design: In one or more implementations, no host        control or input is needed for a secure storage device's normal        operation or management (e.g., to lock the device, unlock the        device, authenticate the device, or encrypt/decrypt data to/from        a mass storage memory), and no software on the host is needed        for the device's normal operation or management (e.g., to lock        the device, unlock the device, authenticate the device, or        encrypt/decrypt data to/from a mass storage memory). In one or        more implementations, a secure storage device is        self-authenticated using its own input device and its own        controller, all of which reside within or on the secure storage        device itself (rather than within or on another device such as        the host). In one or more implementations, during a normal        operation (e.g., a non-configuration-ready mode), a secure        storage device (e.g., its own input device), rather than a host,        receives a valid new PIN(s) for the device from a user. In one        or more implementations, during a normal operation, a secure        storage device receives a PIN (e.g., by its own input device)        and processes the PIN (e.g., by its own controller) to unlock        the device without any input, instructions or data from a host;        thus the device rather than the host receives and processes the        PIN.    -   Configurable: Custom profiles and mass configure multiple secure        keys can be created at once with the configurator application/a        powered hub bundle.    -   Embedded keypad: All PIN entries and controls are performed on        the keypad of a secure storage device. In one or more        implementations, no critical security parameters are ever shared        with the host computer. In one or more implementations, since        there is no host involvement in the key's authentication or        operation, the risk of software hacking and key-logging is        circumvented (or completely circumvented).    -   Super tough, inside and out: A secure storage device's rugged,        extruded aluminum casing and wear-resistant keypad is resistant        to dust and water. Inside, another layer of protection is added        by encasing the inner componentry with a hardened epoxy compound        to prevent physical access to the encryption circuitry.    -   Independent user and administrator PINs: A secure storage device        can be configured with independent user and administrator PINs,        making it an optimal device for corporate and government        deployment. Should a user forget a user PIN, the secure storage        device can still be unlocked with the administrator PIN and a        new user PIN can be created.    -   One-time recovery PINs: In the event that a user PIN is        forgotten, multiple (e.g., four one-time recovery PINs) can be        programmed to permit access to the secure storage device's data.    -   Auto-lock feature: In one or more implementations, a secure        storage device can automatically lock whenever the device is        unplugged from its port (e.g., powered USB port), and is further        programmable to lock after a predetermined period of inactivity.    -   Drive reset feature: This feature allows a secure storage device        to be cleared and redeployed. Capable of generating an infinite        number of randomly generated encryption keys, a secure storage        device can be reset as many times as desired.    -   Brute-force protection: In one or more implementations, after a        predetermined number (programmable, and for example up to        twenty) of incorrect PIN entry attempts, a secure storage device        determines that it is under brute force attack and responds by        performing a crypto-erase, deleting the encryption key which        renders all of the secure storage device's data (e.g., data in        the mass storage memory of the secure storage device) useless.    -   Variable time circuit technology: This technology is designed to        thwart timing attacks aimed at accessing the secure storage        device by studying usage patterns and infiltrating the secure        storage device's electronics.    -   Lock-override mode feature: In one or more implementations, a        secure storage device is allowed to designate specific cases in        which the device needs to remain unlocked, e.g., during reboot,        passing the device through a virtual machine, or other similar        situations that would normally prompt the device to        automatically lock. When enabled, the lock-override mode allows        the device to remain unlocked through communication        re-enumeration (e.g., USB port re-enumeration) and does not        re-lock until the power (e.g., USB power) is interrupted.    -   Read-only mode feature: In one or more implementations,        accessing data on the secure storage device is allowed in a        public setting while protecting against viruses (e.g., USB        viruses). Read-only mode is useful for applications that require        data to be preserved in its original, unaltered state and cannot        be overwritten or modified.    -   Self-destruct feature: In one or more implementations, this        allows the last line of defense for data security where all of        the secure storage device's contents (e.g., data in the mass        storage memory of the secure storage device) need to be wiped to        avert breach. In one or more implementations, a secure storage        device's self-destruct PIN defends against physically        compromising situations by erasing the secure storage device's        contents, leaving it in normal working order and to appear as if        the device has yet to be deployed.

In one or more implementations, a secure storage device 110 may beimplemented with and include one or more of the following features.These features are examples, and the subject technology is not limitedto these examples.

-   -   Easy to use onboard keypad: A secure storage device can be        unlocked with unique 7 to 16-digit pin. A secure storage device        may have wear-resistant keys to obscure use.    -   Programmable minimum PIN length: For added PIN length and        enhanced security, the minimum PIN length requirement can be        increased from 7 characters up to 16 maximum.    -   On-the-fly hardware encryption: In one or more implementations,        all data (e.g., data to be stored on a memory 232) is        hardware-encrypted on-the-fly with military-grade, full-disk        encryption.    -   Software-free/cross-platform compatible: In one or more        implementations, no software is necessary to set up or operate a        secure storage device, and the device is completely        cross-platform compatible and optimal for corporate deployments.    -   Forced-enrollment/user forced enrollment: In one or more        implementations, for added security, a secure storage device        requires that an administrator creates a unique PIN upon first        use and additionally allows forced enrollment feature to be        extended to a user PIN setup.    -   Administrator mode: In one or more implementations, a secure        storage device allows enrollment of one independent user and one        administrator for setting parameters for PIN management,        read-only, auto-lock, self-destruct, lock-override, and brute        force.    -   Secure storage device-reset feature: In one or more        implementations, a secure storage device allows an infinite        number of resets and performs a crypto-erase with new encryption        key regeneration.    -   Auto-lock feature: A secure storage device automatically locks        after a predetermined period of inactivity or whenever the        device is unplugged from its powered communication port (e.g.,        USB port) or if power to the port (e.g., USB port) is turned        off.    -   Internally sealed by tough epoxy compound filling: In one or        more implementations, the internal components of a secure        storage device are sealed by a super-tough epoxy compound        barrier, which prevents would-be hackers from physically        accessing the encryption circuitry.    -   OS and platform independent: A secure storage device is        compatible with Windows®, Mac®, Linux and embedded systems and        works with any other devices such as USB/USB on-the-go devices.    -   Advanced options/modes: A secure storage device may include two        read-only modes, lock-override mode, and a self-destruct feature        with a self-destruct PIN.    -   LED flicker button confirmation: A secure storage device may        include an indicator that indicates a positive button entry with        visual LED confirmation.    -   Recovery PINs: A secure storage device may allow multiple (e.g.,        four) one-time use PINs to recover data in cases of forgotten        user/administrator PINs.    -   USB 3.0 Interface: A secure storage device may be compatible        with any computer USB port or any USB/USB on-the-go devices.    -   Aluminum enclosure: A secure storage device may include dust and        water resistant durable aluminum housing.    -   Secure storage device capacities: In one or more examples, a        secure storage device (e.g., memory 232) may include 8 GB, 16        GB, 32 GB, or 64 GB.    -   Plug-n-play and compatible on any system: A secure storage        device may work with Windows®, Mac®, Linux, Android and Symbian        systems, or any powered USB OS with a storage file system.    -   Secure storage: A secure storage device may be used for        government, health care, insurance companies, financial        institutions, human resource departments, and executives with        sensitive data.    -   Data transfer rates: In one or more examples, a secure storage        device may support 190 MB/s (read)/80 MB/s (write)|small file        (4K): 16 MB/s read; 33 MB/s write.    -   Interface: A secure storage device may support USB 3.0.

FIG. 5 is a block diagram illustrating an exemplary computer system 500with which the host 120 of FIG. 1 can be implemented. In certainaspects, the computer system 500 may be implemented using hardware or acombination of software and hardware, in a dedicated client device,integrated into another entity, or distributed across multiple entities.

The computer system 500 (e.g., host 120) includes a bus 508 or othercommunication mechanism for communicating information, and a processor502 (e.g., processor 212) coupled with the bus 508 for processinginformation. By way of example, the computer system 500 may beimplemented with one or more processors 502. A processor 502 may be ageneral-purpose microprocessor, a microcontroller, a digital signalprocessor, an application specific integrated circuit, discrete hardwarecomponents, or any other suitable hardware that can perform calculationsor other manipulations of information.

The computer system 500 can include, in addition to hardware, code thatcreates an execution environment for the computer program in question,e.g., code that constitutes processor firmware, a protocol stack, adatabase management system, an operating system, or a combination of oneor more of them stored in an included memory 504 (e.g., memory 220),such as a random access memory (RAM), a flash memory, registers, a harddisk, a removable disk or any other suitable storage device, for storinginformation and instructions to be executed by a processor 502.

The instructions may be stored in the memory 504 and implemented in oneor more computer program products, i.e., one or more modules of computerprogram instructions encoded on a computer readable medium for executionby, or to control the operation of, the computer system 500, andaccording to any method well known to those of skill in the art. Thememory 504 may also be used for storing temporary variable or otherintermediate information during execution of instructions to be executedby the processor 502.

A computer program as discussed herein does not necessarily correspondto a file in a file system. A computer program can be deployed to beexecuted on one computer or on multiple computers that are located atone site or distributed across multiple sites and interconnected by acommunication network. The processes and logic flows described in thisdisclosure can be performed by one or more programmable processorsexecuting one or more computer programs to perform functions byoperating on input data and generating output.

The computer system 500 further includes a data storage unit 506 such asa magnetic disk or optical disk, coupled to bus 508 for storinginformation and instructions. The computer system 500 may be coupled viaan input/output module 510 to various devices. Exemplary input/outputmodules 510 include data ports such as USB ports. The input/outputmodule 510 is configured to connect to a communications module 512.Exemplary communications modules 512 (e.g., communications modules 218)include a USB interface and networking interface cards, such as Ethernetcards and modems. In certain aspects, the input/output module 510 isconfigured to connect to a plurality of devices, such as an input device514 (e.g., input device 216) and/or an output device 516 (e.g., outputdevice 214). Exemplary input devices 514 include a keyboard and apointing device. Other kinds of input devices 514 can be used, such as atactile input device, visual input device, audio input device, orbrain-computer interface device. Exemplary output devices 516 includedisplay devices, such as a liquid crystal display (LCD) monitor, fordisplaying information to the user.

According to one aspect of the present disclosure, a computing device(e.g., 500, 120, 110, 200) can be implemented using a computer system inresponse to a processor (e.g., 502, 212, 258, or a sub-component)executing one or more sequences of one or more instructions contained ina memory (e.g., 504, 220, 240). Such instructions may be read into thememory (e.g., 504, 220, 240) from another machine-readable medium, suchas a data storage unit (e.g., 506, 232). Execution of the sequences ofinstructions contained in the memory (e.g., 504, 220, 240) causes theprocessor (e.g., 502, 212, 258, or a sub-component) to perform theprocess steps described herein. One or more processors in amulti-processing arrangement may also be employed to execute thesequences of instructions contained in the memory (e.g., 504, 220, 240).In some aspects, hard-wired circuitry may be used in place of or incombination with software instructions to implement various aspects ofthe present disclosure. Thus, some aspects of the present disclosure arenot limited to any specific combination of hardware circuitry andsoftware.

Various aspects of the subject matter described in this specificationcan be implemented in a computing system that includes a back endcomponent, e.g., as a data server, or that includes a middlewarecomponent, e.g., an application server, or that includes a front endcomponent, e.g., a client computer having a graphical user interface ora Web browser through which a user can interact with an implementationof the subject matter described in this specification, or anycombination of one or more such back end, middleware, or front endcomponents.

The term “machine-readable storage medium” or “computer readable medium”as used herein refers to any medium or media that participate inproviding instructions to a processor (e.g., 502, 212, 258 or asub-component) for execution. Such a medium may take many forms,including, but not limited to, non-volatile media and volatile media.Non-volatile media include, for example, optical or magnetic disks, suchas a data storage unit (e.g., 506, 232). Volatile media include dynamicmemory, such as a memory 504. Common forms of machine-readable mediainclude, for example, a flexible disk, a hard disk, a magnetic medium, aCD-ROM, DVD, any other optical medium, a RAM, a PROM, an EEPROM, a FLASHEPROM or any other medium from which a computer can read. Themachine-readable storage medium can be a machine-readable storagedevice, a machine-readable storage substrate, a memory device, or acombination of one or more of them.

Various examples of aspects of the disclosure are described below asclauses for convenience. These are provided as examples, and do notlimit the subject technology.

Clause A. A secure storage device (e.g., 110), comprising: a casing; amemory disposed within the casing and configured to store secure data; aphysical key input device disposed at an outer surface of the casing andconfigured to receive a security identification code from a user tofacilitate authentication and unlocking of the secure storage device; acommunication interface configured to connect the secure storage deviceto a communication bus external to the casing; and a controller disposedwithin the casing and coupled to the memory and the physical key inputdevice, the controller configured to cause: determining whether thesecure storage device is in a configuration-ready mode, theconfiguration-ready mode indicating that the secure storage device isallowed to communicate with a host, which is external to the securestorage device, to configure the secure storage device; and receivingconfiguration data from the host via the communication bus forconfiguring the secure storage device when the secure storage device isdetermined to be in the configuration-ready mode, the secure storagedevice being prevented from receiving the configuration data from thehost when the secure storage device is determined not to be in theconfiguration-ready mode.

Clause B. Wherein an indication whether the secure storage device is inthe configuration-ready mode is contained within the secure storagedevice, and

Clause C. Wherein prior to receiving the configuration data from thehost, when the secure storage device is in the configuration-ready modeand contains a security identification code, the security identificationcode contained in the secure storage device is a null securityidentification code that is unusable to facilitate unlocking the securestorage device after the secure storage device is locked.

Clause D. Wherein prior to receiving the configuration data from thehost, when the secure storage device is in the configuration-ready modeand contains a security identification code, the security identificationcode contained in the secure storage device is a null securityidentification code, at least a portion of which is not enterable viathe physical key input device.

Clause E. Wherein the secure storage device (e.g., the controller) isconfigured to store the configuration data received from the host toconfigure the secure storage device with the configuration data receivedfrom the host.

Clause F. Wherein after the secure storage device is configured with theconfiguration data from the host, the secure storage device is preventedfrom re-configured by the host when the secure storage device contains asecurity identification code usable to unlock the secure storage device.

Clause G. Wherein when the secure storage device is set to a secondconfiguration-ready mode after a non-configuration-ready mode, thesecure storage device is configured to use a second handshake key and asecond configuration encryption key that are different from thehandshake key and the configuration encryption key used for a firstconfiguration-ready mode.

Clause H. A method for facilitating configuration of a secure storagedevice (e.g., 110) in a configuration-ready mode, the method comprising:determining whether at least a secure storage device, which is externalto a host, is in a configuration-ready mode, the configuration-readymode indicating that the host is allowed to communicate with the securestorage device to configure the secure storage device; and providing,for transmission to the secure storage device, configuration data forconfiguring the secure storage device when the secure storage device is,or is determined to be, in the configuration-ready mode, the host beingprevented from configuring the secure storage device when the securestorage device is not, or is determined to be not, in theconfiguration-ready mode.

Clause I. The method comprising: prior to providing the configurationdata, selecting a configuration profile for the secure storage devicewhen the secure storage device is, or is determined to be, in theconfiguration-ready mode.

Clause J. The method comprising: prior to providing the configurationdata, facilitating a handshake with the secure storage device based on ahandshake key.

Clause K. The method comprising: prior to providing the configurationdata, facilitating establishment of a configuration encryption key forthe configuration data.

Clause L. The method comprising: prior to providing the configurationdata, encrypting the configuration data using the configurationencryption key.

Clause M. Wherein the handshake key is different from the configurationencryption key.

Clause N. Wherein when the secure storage device is set to a secondconfiguration-ready mode after a non-configuration-ready mode, the hostis configured to use a second handshake key and a second configurationencryption key that are different from a handshake key and aconfiguration encryption key used for a first configuration-ready mode.

Clause O. The method comprising: storing the selected configurationprofile.

Clause P. The method comprising: facilitating termination ofcommunication with the secure storage device.

Clause Q. A computer-readable storage medium (e.g., 220, one or morememories, one or more registers, and/or one or more media) storinginstructions that, when executed by one or more processors (e.g., 212),cause one or more processors to perform the method described in any ofClauses H-P or any of other operations described herein.

Clause O. A computer-readable storage medium (e.g., 240, 232, one ormore memories, one or more registers, and/or one or more media) storinginstructions that, when executed by one or more processors (e.g., 258),cause one or more processors to perform the method described in any ofClauses A-G or any of other operations described herein.

In one or more aspects, additional clauses are described below.

A method comprising one or more methods or operations described herein.

An apparatus comprising one or more memories (e.g., 240, 232, 220, oneor more memories, or one or more registers) and one or more processors(e.g., 258, 212) coupled to the one or more memories, the one or moreprocessors configured to cause the apparatus to perform one or moremethods or operations described herein.

A hardware apparatus comprising circuits (e.g., 258, 212) configured toperform one or more methods, operations, or portions thereof describedherein.

An apparatus comprising means (e.g., 258, 212) adapted for performingone or more methods or operations described herein.

A computer-readable storage medium (e.g., 240, 232, 220, one or morememories, one or more registers, and/or one or more media) comprisinginstructions stored therein, the instructions comprising code forperforming one or more methods or operations described herein.

A computer-readable storage medium (e.g., 240, 232, 220, one or morememories, one or more registers, and/or one or more media) storinginstructions that, when executed by one or more processors (e.g., 258,212), cause one or more processors to perform one or more methods,operations or portions thereof described herein.

In one aspect, a method may be an operation, an instruction, or afunction and vice versa. In one aspect, a clause or a claim may beamended to include some or all of the words (e.g., instructions,operations, functions, or components) recited in other one or moreclauses, one or more sentences, one or more phrases, one or moreparagraphs, and/or one or more claims. A clause or a claim may havemultiple dependencies based on any of the other clauses or claims.

An example of the present disclosure may be an article of manufacture inwhich a non-transitory machine-readable medium (such as microelectronicmemory) has stored thereon instructions which program one or more dataprocessing components (generically referred to here as a “processor” or“processing unit”) to perform the operations described herein. In otherexamples, some of these operations may be performed by specific hardwarecomponents that contain hardwired logic. Those operations mayalternatively be performed by any combination of programmed dataprocessing components and fixed hardwired circuit components.

In some cases, an example of the present disclosure may be an apparatus(e.g., a secure flash storage device) that includes one or more hardwareand firmware/software logic structure for performing one or more of theoperations described herein. For example, as described above, theapparatus may include a memory unit, which stores instructions that maybe executed by a hardware processor installed in the apparatus. Theapparatus may also include one or more other hardware or softwareelements, including a network interface, a display device, etc.

To illustrate the interchangeability of hardware, firmware and software,items such as the various illustrative blocks, modules, components,methods, operations, instructions, and algorithms have been describedgenerally in terms of their functionality. Whether such functionality isimplemented as hardware, firmware or software depends upon theparticular application and design constraints imposed on the overallsystem. Skilled artisans may implement the described functionality invarying ways for each particular application.

A reference to an element in the singular is not intended to mean oneand only one unless specifically so stated, but rather one or more. Forexample, “a” module may refer to one or more modules. An elementproceeded by “a,” “an,” “the,” or “said” does not, without furtherconstraints, preclude the existence of additional same elements.

Headings and subheadings, if any, are used for convenience only and donot limit the invention. The word exemplary is used to mean serving asan example or illustration. To the extent that the term include, have,contain or the like is used, such term is intended to be inclusive in amanner similar to the term comprise as comprise is interpreted whenemployed as a transitional word in a claim. Relational terms such asfirst and second and the like may be used to distinguish one entity oraction from another without necessarily requiring or implying any actualsuch relationship or order between such entities or actions. The termcoupling, connecting, or the like is intended to include direct andindirect coupling and direct and indirect connecting. The term coupled,connected, or the like is intended to include directly and indirectlycoupled and directly and indirectly connected.

Phrases such as an aspect, the aspect, another aspect, some aspects, oneor more aspects, an implementation, the implementation, anotherimplementation, some implementations, one or more implementations, anembodiment, the embodiment, another embodiment, some embodiments, one ormore embodiments, a configuration, the configuration, anotherconfiguration, some configurations, one or more configurations, thesubject technology, the disclosure, the present disclosure, othervariations thereof and alike are for convenience and do not imply that adisclosure relating to such phrase(s) is essential to the subjecttechnology or that such disclosure applies to all configurations of thesubject technology. A disclosure relating to such phrase(s) may apply toall configurations, or one or more configurations. A disclosure relatingto such phrase(s) may provide one or more examples. A phrase such as anaspect or some aspects may refer to one or more aspects and vice versa,and this applies similarly to other foregoing phrases.

A phrase “at least one of” preceding a series of items, with the terms“and” or “or” to separate any of the items, modifies the list as awhole, rather than each member of the list. The phrase “at least one of”does not require selection of at least one item; rather, the phraseallows a meaning that includes at least one of any one of the items,and/or at least one of any combination of the items, and/or at least oneof each of the items. By way of example, each of the phrases “at leastone of A, B, and C” or “at least one of A, B, or C” refers to only A,only B, or only C; any combination of A, B, and C; and/or at least oneof each of A, B, and C.

It is understood that the specific order or hierarchy of steps,operations, or processes disclosed is an illustration of exemplaryapproaches. Unless explicitly stated otherwise, it is understood thatthe specific order or hierarchy of steps, operations, or processes maybe performed in different order. Some of the steps, operations, orprocesses may be performed simultaneously. The accompanying methodclaims, if any, present elements of the various steps, operations orprocesses in a sample order, and are not meant to be limited to thespecific order or hierarchy presented. Unless explicitly statedotherwise, these may be performed in serial, linearly, in parallel or indifferent order. It should be understood that the describedinstructions, operations, and systems can generally be integratedtogether in a single software/hardware product or packaged into multiplesoftware/hardware products.

The disclosure is provided to enable any person skilled in the art topractice the various aspects described herein. In some instances,well-known structures and components are shown in block diagram form inorder to avoid obscuring the concepts of the subject technology. Thedisclosure provides various examples of the subject technology, and thesubject technology is not limited to these examples. Variousmodifications to these aspects will be readily apparent to those skilledin the art, and the principles described herein may be applied to otheraspects.

All structural and functional equivalents to the elements of the variousaspects described throughout the disclosure that are known or later cometo be known to those of ordinary skill in the art are expresslyincorporated herein by reference and are intended to be encompassed bythe claims. Moreover, nothing disclosed herein is intended to bededicated to the public regardless of whether such disclosure isexplicitly recited in the claims. No claim element is to be construedunder the provisions of 35 U.S.C. § 112, sixth paragraph, unless theelement is expressly recited using a phrase means for or, in the case ofa method claim, the element is recited using the phrase step for.

The title, background, brief description of the drawings, abstract, anddrawings are hereby incorporated into the disclosure and are provided asillustrative examples of the disclosure, not as restrictivedescriptions. It is submitted with the understanding that they will notbe used to limit the scope or meaning of the claims. In addition, in thedetailed description, it can be seen that the description providesillustrative examples and the various features are grouped together invarious implementations for the purpose of streamlining the disclosure.The method of disclosure is not to be interpreted as reflecting anintention that the claimed subject matter requires more features thanare expressly recited in each claim. Rather, as the following claimsreflect, inventive subject matter lies in less than all features of asingle disclosed configuration or operation. The following claims arehereby incorporated into the detailed description, with each claimstanding on its own as a separately claimed subject matter.

The claims are not intended to be limited to the aspects describedherein, but are to be accorded the full scope consistent with thelanguage claims and to encompass all legal equivalents. Notwithstanding,none of the claims are intended to embrace subject matter that fails tosatisfy the requirements of the applicable patent law, nor should theybe interpreted in such a way.

What is claimed is:
 1. A secure storage device, comprising: a casing; amemory disposed within the casing and configured to store secure data; aphysical key input device disposed at an outer surface of the casing andconfigured to receive a security identification code from a user tofacilitate authentication and unlocking of the secure storage device; acommunication interface configured to connect the secure storage deviceto a communication bus external to the casing; and a controller disposedwithin the casing and coupled to the memory and the physical key inputdevice, the controller configured to cause: determining whether thesecure storage device is in a configuration-ready mode, theconfiguration-ready mode indicating that the secure storage device isallowed to communicate with a host, which is external to the securestorage device, to configure the secure storage device; and receivingconfiguration data from the host via the communication bus forconfiguring the secure storage device when the secure storage device isdetermined to be in the configuration-ready mode, the secure storagedevice being prevented from receiving the configuration data from thehost when the secure storage device is determined to be not in theconfiguration-ready mode, wherein an indication whether the securestorage device is in the configuration-ready mode is contained withinthe secure storage device, and wherein prior to receiving theconfiguration data from the host, when the secure storage device is inthe configuration-ready mode and contains a security identificationcode, the security identification code contained in the secure storagedevice is a null security identification code that is unusable tofacilitate unlocking the secure storage device after the secure storagedevice is locked.
 2. The secure storage device of claim 1, wherein priorto initiating a communication with the host, when the secure storagedevice is in the configuration-ready mode and contains an encryptionkey, the encryption key is a new encryption key that is unusable fordecrypting encrypted data previously stored in the memory.
 3. The securestorage device of claim 1, wherein prior to receiving the configurationdata from the host, when the secure storage device is in theconfiguration-ready mode and contains another security identificationcode, the another security identification code contained in the securestorage device is another null security identification code that isunusable to create a new security identification code to unlock thesecure storage device after the secure storage device is locked.
 4. Thesecure storage device of claim 1, wherein prior to receiving theconfiguration data from the host, at least a portion of the securityidentification code contained in the secure storage device is notenterable via the physical key input device.
 5. The secure storagedevice of claim 1, wherein the controller is configured to cause: priorto determining whether the secure storage device is in theconfiguration-ready mode, setting the secure storage device into theconfiguration-ready mode, wherein setting the secure storage device intothe configuration-ready mode comprises: setting the securityidentification code in the secure storage device into the null securityidentification code that is unusable to unlock the secure storage deviceafter the secure storage device is locked.
 6. The secure storage deviceof claim 5, wherein setting the secure storage device into theconfiguration-ready mode comprises: setting an encryption key in thesecure storage device into a new encryption key that is unusable fordecrypting data previously stored in the secure storage device.
 7. Thesecure storage device of claim 5, wherein setting the secure storagedevice into the configuration-ready mode comprises: setting theindication to indicate that the secure storage device is in theconfiguration-ready mode.
 8. The secure storage device of claim 1,wherein the controller is configured to cause: receiving an input viathe physical key input device when the secure storage device is not inthe configuration-ready mode, wherein based on the input, the controlleris configured to place the secure storage device into theconfiguration-ready mode.
 9. The secure storage device of claim 8,wherein the controller is configured to cause: in response to the input,setting the security identification code in the secure storage deviceinto the null security identification code, wherein at least a portionof the null security identification code is not enterable via thephysical key input device; and setting an encryption key in the securestorage device into a new encryption key that is unusable for decryptingdata previously stored in the memory.
 10. The secure storage device ofclaim 1, wherein the configuration data from the host comprises asecurity identification code that is enterable using the physical keyinput device of the secure storage device.
 11. The secure storage deviceof claim 1, wherein the controller is further configured to cause: inresponse to receiving the configuration data from the host, decryptingthe received configuration data; storing the configuration data in thesecure storage device; and completing configuration of the securestorage device, wherein the controller is configured to store anindication that the secure storage device is not in theconfiguration-ready mode when the configuration of the secure storagedevice is complete.
 12. The secure storage device of claim 11, whereinthe controller is configured to cause: ending communication with thehost when the configuration of the secure storage device is completed;and preventing a new configuration of the secure storage device by thehost subsequent to ending the communication with the host, based on theindication that the secure storage device is not in theconfiguration-ready mode.
 13. The secure storage device of claim 1,wherein prior to receiving the configuration data from the host, whenthe secure storage device is in the configuration-ready mode, the securestorage device contains no security identification code that is usableto unlock the secure storage device after the secure storage device islocked.
 14. The secure storage device of claim 1, wherein when thesecure storage device is determined to be in the configuration-readymode, the controller is configured to send an instruction prior toreceiving the configuration data from the host, the instruction forproviding identifier information associated with the secure storagedevice to the communication interface for provision to the host.
 15. Thesecure storage device of claim 14, wherein the identifier informationcomprises a product identifier and a vendor identifier of the securestorage device, and wherein in response to a query from the host, thecontroller is configured to provide, for transmission to the host, theindication whether the secure storage device is in theconfiguration-ready mode.
 16. The secure storage device of claim 1,wherein when the secure storage device is determined to be in theconfiguration-ready mode, the controller is configured to cause: priorto receiving the configuration data, facilitating a handshake processwith the host; prior to receiving the configuration data, facilitatingestablishment of a configuration encryption key for the configurationdata; after receiving the configuration data, decrypting theconfiguration data based on the configuration encryption key; storingthe configuration data in the secure storage device; and setting thesecure storage device into a non-configuration-ready mode, wherein theconfiguration encryption key is different from a data transferencryption key for encrypting data to the memory or decrypting data fromthe memory, and wherein when the secure storage device is set to asecond configuration-ready mode after the non-configuration-ready mode,the secure storage device is configured to use a second configurationencryption key that is different from the configuration encryption key.17. The secure storage device of claim 1, wherein the configuration datafrom the host comprises a security identification code and one or moreother configuration settings associated with configuration of the securestorage device, and wherein the security identification code of theconfiguration data from the host is usable to facilitate unlocking thesecure storage device after the secure storage device is locked.
 18. Thesecure storage device of claim 1, comprising: an output device disposedat the outer surface of the casing and configured to display anindication of a mode of operation of the secure storage device, whereinthe indication of the mode of operation includes a signal indicating theconfiguration-ready mode when the secure storage device is in theconfiguration-ready mode.
 19. A secure storage device, comprising: acasing; a memory disposed within the casing and configured to storeencrypted data; a physical input device disposed at an outer surface ofthe casing and configured to receive a security identification code tofacilitate unlocking of the secure storage device; and a controllerdisposed within the casing and coupled to the memory and the physicalinput device, the controller configured to cause: determining whetherthe secure storage device is in a configuration-ready mode, theconfiguration-ready mode indicating that the secure storage device isallowed to communicate with a host, which is external to the securestorage device, to configure the secure storage device; and receivingconfiguration data from the host for configuring the secure storagedevice when the secure storage device is determined to be in theconfiguration-ready mode, the secure storage device being prevented fromreceiving the configuration data from the host when the secure storagedevice is determined to be not in the configuration-ready mode, whereinprior to receiving the configuration data from the host, when the securestorage device is in the configuration-ready mode and contains asecurity identification code, the security identification code containedin the secure storage device is a null security identification code, atleast a portion of which is not enterable via the physical input device.20. A secure storage device, comprising: a housing; a memory disposedwithin the housing and configured to store secure data; a physical inputdevice disposed at an outer surface of the housing and configured toreceive a security identification code to facilitate unlocking of thesecure storage device; and a controller disposed within the housing andcoupled to the memory and the physical input device, the controllerconfigured to cause: determining that the secure storage device is in aconfiguration-ready mode, the configuration-ready mode indicating thatthe secure storage device is allowed to communicate with a host, whichis external to the secure storage device, to configure the securestorage device; and receiving configuration data from the host forconfiguring the secure storage device when the secure storage device isin the configuration-ready mode, the secure storage device beingprevented from receiving the configuration data from the host when thesecure storage device is not in the configuration-ready mode, wherein anindication that the secure storage device is in the configuration-readymode is contained within the secure storage device.